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Title:
INK JET RECORDING HEAD APPARATUS
Document Type and Number:
WIPO Patent Application WO/1998/003338
Kind Code:
A1
Abstract:
An ink jet recording head (10) having a substrate (12) for supporting pressure generating element (14); conductors (16a, 16b, 16c, etc.) for providing both a means of electrical connection to the pressure generating element (14) at taps (20) and side walls for ink channels (18a, 18b, 18c, etc.); and a cover. A voltage pulse applied to selected conductors causes a pressure pulse in a channel which in turn causes a drop of ink (22) to be ejected from the ends of the ink channel.

Inventors:
BOBRY HOWARD H (US)
Application Number:
PCT/US1997/013038
Publication Date:
January 29, 1998
Filing Date:
July 01, 1997
Export Citation:
Click for automatic bibliography generation   Help
Assignee:
BOBRY HOWARD H (US)
International Classes:
B41J2/045; B41J2/05; B41J2/14; B41J2/155; (IPC1-7): B41J2/05
Foreign References:
US4479135A1984-10-23
US4588998A1986-05-13
US4695853A1987-09-22
US5223853A1993-06-29
US5504505A1996-04-02
Attorney, Agent or Firm:
Rankin, Carl A. (Hill Lewis & Clark, 700 Huntington Building, 925 Euclid Avenu, Cleveland OH, US)
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Claims:
CLAIMS
1. In an ink jet recording head including an ink reservoir, electrical elements for selectively generating discrete fluid pressure pulses to cause ink to be ejected in predetermined patterns and a plurality of taps operatively connected to said electrical elements, the improvement comprising a dielectric substrate having a top face, a dielectric cover spaced above said top face, a plurality of electπcal conductors disposed between said substrate and said cover, each of said conductors being operatively connected to one of said taps, said top face, cover and electrical conductors defining a plurality of ink flow channels, said flow channels communicating at one end thereof with said ink reservoir, the other end of each respective flow channel being open to define an ink ejection nozzle .
2. The apparatus of claim 1 wherein said electrical elements are exothermic elements.
3. The apparatus of claim 2 wherein said exothermic elements have a nonzero temperature coefficient of resistance.
4. The apparatus of claim 3 wherein said temperature coefficient of resistance is positive and nonlinear over a temperature range including a maximum desired operating temperature.
5. The apparatus of claim 1 wherein said electπcal elements are piezoelectπc elements.
6. The apparatus of claim 1 wherein said ink reservoir compπses a bladder.
7. The apparatus of claim 1 wherein said ink reservoir compπses an ink saturated pad.
8. The apparatus of claim 1 wherein said cover comprises an inksaturated pad.
9. The apparatus of claim 1 wherein said substrate is flat.
10. The apparatus of claim I wherein said substrate is curved 1 1 The apparatus of claim 1 wherein said substrate is cylindrical 12 The apparatus of claim 1 wherein said substrate is formed into a spiral 13 The apparatus of claim 1 wherein said ink flow channels are disposed parallel to each other 14 The apparatus of claim 1 wherein said ink flow channels are disposed at divergent angles to each other 15 The apparatus of claim 1 wherein said ink flow channels are disposed at convergent angles to each other 16 The apparatus of claim 1 wherein said ink flow channels are dielectπcally insulated 17 The apparatus of claim 1 wherein said plurality of taps are N+l in number and said electrical elements are N in number and wherein a first tap group, comprising every alternate one of said taps, is electrically connected via a first group of said conductors to a first set of electrodes, N': in number, and a second tap group, comprising all taps not included in said first tap group, is electrically connected by a second group of said conductors to a second set of electrodes, also N : in number 18 An ink jet recording head apparatus comprising a pressure generating element divided into a number of portions, N, by a plurality of taps, N+l , each tap having a conductor extending therefrom, where a first tap group, comprising every alternate one of said taps, is electrically connected via a first group of said conductors to a first set of electrodes, N'1 in number, and a second tap group, comprising all taps not included in said first tap group, are electrically connected by a second group of said conductors to a second set of electrodes, also N"' in number 19 The apparatus of claim 18 wherein said first tap group comprises a first tap, located at one end of said pressure generating element, and all other odd numbered taps of the element, and wherein said second group of taps comprises a second tap, located adjacent to said first tap, and all other even numbered taps of the element 20 In an ink jet recording head including an ink reservoir and electrical elements for selectively generating discrete fluid pressure pulses to cause ink to be ejected in predetermined patterns, the improvement wherein said ink reservoir comprises an ink saturated pad 21 In an ink jet recording head including an ink reservoir and electrical elements for selectively generating discrete fluid pressure pulses to cause ink to be ejected in predetermined patterns, the improvement wherein said electrical elements comprise exothermic elements having a positive temperature coefficient of resistance that is nonlinear over a temperature range that includes a maximum desired operating temperature 22 A method for driving an exothermic pressure generating element portion and limiting the temperature thereof to a desired maximum, comprising the steps of measuring the time elapsed since the last previous application of a drive pulse to said element portion; calculating the present temperature of the element portion using said elapsed time and the known thermal time constant for the element portion, calculating the energy required to be applied to the element portion in order to increase its temperature to the desired maximum; calculating the drive pulse width required to supply said required energy to the element portion; applying a drive pulse to the element portion, and terminating the drive pulse when said drive pulse width required has been achieved 23 A method for driving an exothermic pressure generating element portion having a nonzero temperature coefficient of resistance, and limiting the temperature thereof to a desired maximum, comprising the steps of calculating the resistance of said element portion corresponding to said desired maximum temperature using the temperature coefficient of resistance of the element, applying a known voltage across the element portion, calculating the magnitude of the current through the element portion corresponding to the desired maximum element portion temperature using said calculated resistance and said known voltage, monitoring the magnitude of the actual current through the element portion; comparing said actual current magnitude to said calculated current magnitude; and terminating the application of voltage across the element portion when the actual current magnitude equals the calculated current magnitude 24 A method for driving an exothermic pressure generating element portion having a nonzero temperature coefficient of resistance, and limiting the temperature thereof to a desired maximum, comprising the steps of calculating the resistance of said element portion corresponding to said desired maximum temperature using the temperature coefficient of resistance of the element; applying a known current through the element portion, calculating the magnitude of the voltage across the element portion corresponding to the desired maximum element portion temperature using said calculated resistance and said known current, monitoring the magnitude of the actual voltage across the element portion, comparing said actual voltage magnitude to said calculated voltage magnitude, and terminating the application of current through the element portion when the actual voltage magnitude equals the calculated voltage magnitude 25 A method for driving an exothermic pressure generating element portion, and limiting the temperature thereof to a desired maximum, comprising the steps of selecting an exothermic pressure generating element having a temperature coefficient of resistance which is positive and nonlinear over a temperature range which includes said desired maximum, said element being characterized by an initial resistance which increases to a higher final resistance as the desired maximum temperature is approached, applying a voltage across said element portion, where said voltage acting upon said initial resistance of the element portion produces a desired rate of temperature rise, and maintaining the voltage across the element portion, where said voltage acting upon said final resistance causes no further increase in the temperature of the element portion 26 A method of driving an ink jet recording head having a pressure generating element divided into a number, N, of portions, by a plurality, N+l, of taps, each tap having an electrical conductor extending therefrom, and providing means of electπcal connection thereto, comprising the steps of applying a first digital word comprised of N" bits to a first set of electrodes connecting to every alternate one of said conductors, and applying a second digital word compπsed of N'" bits to a second set of electrodes connecting to every one of said conductors not connected by said first set of electrodes, where the bits of said first digital word are selectively either driven by a pulse source referenced to a circuit common or open circuited, and where the bits of said second digital word are selectively either connected to said circuit common or open circuited.
Description:
INK JET RECORDING HEAD APPARATUS

BACKGROUND OF THE INVENTION

The invention relates to an ink jet recording head More particularly, the invention relates to a drop-on-demand, or impulse, ink jet recording head of simplified construction and drive requirements. Impulse ink jet recording heads project ink drops to a recording medium in response to brief pulses of electrical energy applied to one or more thermal or piezoelectric pressure generating elements. These devices are well known and are commonly used for printing information on a medium, such as in computer printers to record text and graphics on paper Ink jet recording heads known heretofore are generally constructed of two or more precision components, which must be assembled with great care to achieve proper alignment.

Additionally, such heads require a large number of driving sources and electrodes to provide connection thereto. Further, ink drop trajectories are not well controlled, so the distance between the recording head and the medium must be minimized It is desirable, for the sake of reduced mechanical complexity and cost, to produce a recording head having the ability to print a wide swath, even a full line at a time, and to allow an increased distance between the recording head and the medium, with improved ink drop trajectory control. The aforesaid factors, however, conspire to limit the practical size, and hence the print swath, of ink jet recording heads built according to the prior art.

The objectives exist, therefore, for an ink jet recording head apparatus of simplified construction, and simplified methods of construction; and requiring a reduced number of driving sources and electrodes, and simplified driving methods, thereby reducing manufacturing costs and enabling the construction of wide swath recording heads It is a further objective to provide improved control of ink drop trajectories, enabling an increased recording head to medium distance.

SUMMARY OF THE INVENTION

To the accomplishment of the foregoing objectives, the present invention contemplates an ink jet recording head of simplified construction, comprising a substrate; a tapped pressure

generating element, the taps dividing said element into a number, N, of portions, a plurality, numbeπng N+l, of conductors, connecting said taps and comprising the side walls of a number, N, of ink flow channels, each of which terminates in a nozzle, electrodes interconnecting said conductors in an interdigitated pattern such that only 2XN'" driving sources and electrode connections are required Another aspect of the present invention is the ability to control the distance between the pressure generating element segments and the nozzles, thus affording supeπor control over ink drop trajectories A further aspect is control of exothermic pressure generating element temperature, resulting in enhanced drop trajectory control These and other aspects and advantages of the present invention will be readily understood and appreciated by those skilled in the art from the following detailed description of the preferred embodiments with the best mode contemplated for practicing the invention in view of the accompanying drawings

BRIEF DESCRIPTION OF THE DRAWINGS

Fig 1 is a simplified perspective view in somewhat schematic form illustrating a portion of an ink jet recording head according to the present invention, Fig 2 is an end elevation of the device of Fig 1 ,

Fig 3 illustrates an alternative embodiment of the device of Fig 1, having ink channels disposed at divergent angles, Fig 4 illustrates an alternative embodiment of the device of Fig 1 having a pressure generating element which overlays the conductors,

Fig 5 is an electrical schematic illustrating a method for reducing the number of electrodes and drive sources required,

Fig 6 illustrates an arrangement of drive switches and a driving pulse source applied as a first digital word, and

Fig 7 illustrates an arrangement of drive switches and a circuit common applied as a second digital word

DETAILED DESCRIPTION OF THE INVENTION

With reference to Figs 1 & 2, an embodiment of one aspect of the invention is illustrated in simplified schematic form for purposes of describing the basic concepts of the invention In this basic configuration, an ink jet recording head 10 is illustrated A significant feature of this device is that it is formed by conventional and well known etching and plating techniques, on a single substrate, with no assembly of separate precision components required The device 10 includes a substrate 12 which may be made from plastic, glass, ceramic, coated metal, or other suitable material The substrate 12 preferably is a dimensionally stable structure with an electrically insulating surface While the substrate may be flat, it can also be of such other shape as may be convenient for the desired application, and may in fact be curved or cylindrical, or may be comprised of a non-πgid material such that it may be formed into a desired shape, such as, for example, a spiral, after fabπcation

The substrate 12 supports a pressure generating element 14, which may be, for example, an exothermic element comprised of an electrically resistive thin film of metal or metal oxide Suitable materials include, for example, indium tin oxide which is well known and commonly used to create conductor patterns on glass surfaces used in liquid crystal displays, and to fabricate thin film resistors The element 14 may be applied to substrate 12 by, for example, a vapor deposition process as is well known Alternatively, pressure generating element 14 may be a piezoelectric element comprised of a material having piezoelectric properties such as, for example, polyvmylidene fluoride (PVDF), marketed by

AMP Incorporated under the Kynar® name, and attached to the substrate by adhesive bonding

The substrate 12 also has applied to it a number of conductors 16a, 16b, 16c, etc These conductors serve not only to provide a means of electπcal connection to the pressure generating element 14 at taps 20, but also as side walls for ink channels or capillaries 18a, 18b,

18c, etc Conductors 16 may be comprised of copper, and fabπcated upon the substrate using conventional pπnted circuit fabrication techniques as are well known A cover (not shown) may be adhesively bonded to the conductors 16, or, alternatively, held in place by some clamping means (not shown), comprising the fourth and final side of the ink channels 18 Ink may be introduced into the ink channels from an ink supply bladder, as in the pπor an (not

shown), or, alternatively, an ink saturated pad. In one embodiment, said ink saturated pad not only serves as an ink supply, but is also used as a cover. Capillary action fills the ink channels 18 with ink.

When an appropriate voltage pulse is applied across adjacent conductors, 16a & 16b, for example, that same pulse is applied across that portion of the pressure generating element

14 which lies between the conductors, and energizes that portion of the element. In the case of an exothermic pressure generating element, a heat pulse vaporizes ink, creating a bubble, which in turn causes a drop of ink 22 to be ejected from the end of the ink channel 18a No separate nozzle structure is required: the end of the ink channel comprises the nozzle. Where a piezoelectric pressure generating element is used, the applied voltage pulse causes an increase in size of that portion of the element 14 across which it has been applied, resulting in a pressure pulse which in turn causes a drop of ink 22 to be ejected from the end of the ink channel

This structure has several advantages over the prior art The pressure generating element 14 may be spaced some distance from the end of the ink channel as shown This results in the ink drop being ejected from what is, effectively, a longer nozzle, like a rifle barrel, thus affording more control over the drop's trajectory. The drop will travel along a path which is an extension of the ink channel, and the angle between adjacent ink channels may, if desired, be made divergent, so that ink drops are ejected from adjacent nozzles on divergent paths. A portion of such a recording head is shown in figure 3. Similarly, ink channels may be disposed at convergent angles, so that ink drops are projected on convergent paths.

While one sequence of fabrication has been described for illustrative purposes, it is recognized and understood that a number of means may be used to achieve the same results. It may, for instance, be desirable in some instances to fabricate the conductors upon the substrate prior to the application of the pressure generating element. Placement of the element 14 above, rather than below, the conductors 16 is illustrated in Fig. It is also possible to place the pressure generating element on the cover. Electrical contact between the element and the conductors is achieved in this case by pressure applied by a clamping device, or by a conductive adhesive.

Because the recording head described is fabricated by deposition, plating, and etching

processes on a single substrate, no precision assembly is required The cover is uniform and its position on the head is not critical, except in the case where the pressure generating element 14 has been fabricated on the cover, and even here positioning is semi-critical in only one dimension. It is noteworthy that the processes used in the fabrication of the head are routinely used in the manufacture of printed circuit boards on a low cost, mass production basis. Recording heads made as herein described may be fabricated on large sheets of substrate material, comprising a large number of heads, which are then cut into individual units. While similar methods are used to produce the separate components of recording heads according to the prior art, subsequent precision assembly is required. As has been described, the recording head is driven by a voltage pulse applied across two adjacent conductors, one on either side of the element portion to be energized, corresponding to the nozzle from which an ink drop is to be expelled. If it is desired that only one portion at a time be energized, then the drive circuitry can simply apply a pulse as described, while all other conductors are left open circuited It is noteworthy that in this recording head configuration one cannot simply hold all conductors "low" while driving only the selected line "high", because to do so would result in two element portions being energized, one on either side of the conductor driven high during the firing pulse. For example, referring to Figs. 1 & 2, assume that conductor 16b is driven high, while all other conductors (including 16a & 16c) are low Voltage will appear across the element 14 portions in both ink channels 18a & 18b, energizing both and causing an ink drop to be expelled from both corresponding nozzles. In order to energize only 18a, 16a should be held low, and 16b driven high (or vice versa), with 16c open circuited.

Alternatively, 16a could be driven high, 16b held low, and 16c (and all other conductors to the right of 16c) also held low. Or, 16a could be held low, and 16b, 16c. etc. all driven high This serves to illustrate that with this recording head design, an element poπion is energized only in response to a voltage difference. Any element portion with a high on one side, and a low on the other, will be energized.

Taking any desired print line, an appropriate drive signal can be derived by starting from one end, arbitrarily making the first conductor either high or low, then applying either the same or different voltage to the next conductor, depending upon whether the first element portion is to be energized or not. The third conductor voltage is made the same as, or

different from, that of the second conductor, depending upon whether the second element portion should be energized, and so on, until all conductor voltages have been defined. An appropriate combination of conductors pulsed high and conductors held low (or vice versa) can be used to print any desired combination of dots. According to the prior art, ink jet recording heads have typically required N+ 1 connections or electrodes, and N+ l drive sources or switching devices to drive N nozzles Typically, each nozzle (corresponding to a pressure generating element portion) is addressed by one individual electrode, and by a single electrode common to all elements. One known method of reducing the required number of electrodes and drivers is to arrange the elements in groups, with each group having its own common electrode The recording head of the present invention does not lend itself to a reduction in electrodes in this manner, because there are no common electrodes. As has been described, each nozzle is driven by a differential voltage applied across its corresponding element portion's adjacent conductors, and not by a signal applied with respect to some common reference It is, nonetheless, possible to reduce the number of electrodes and drivers required to drive the present recording head, as will be described This technique results in a reduction of the number of required electrodes and drivers for a head of N nozzles from N+l to 2XN' : If, for example, a head has 100 nozzles, just 20 connections and drivers will be required, rather than 101 Where N' J is not an integer, it must be rounded up to the next integral number The head is driven by two digital words, each having N w bits. Referring to Fig 5, for purposes of example a head of N = 36 nozzles is shown, with Word 1 having N'" (i.e. 6) bits identified as A-F, while Word 2 has 6 bits identified as U-Z For one word, e.g. Word 1, each bit is binary, but the two binary states are not high and low, but rather high (connected to a pulse source) and open This is readily implemented using a single switching device per bit, connected to a driving pulse source (Fig. 6). The other word, Word 2, is similarly comprised of binary bits where the two states are low (connected to a circuit common or ground) or open (Fig. 7). While the switching devices shown in Figs. 6 & 7 are bipolar transistors, it will be readily appreciated that other devices such as, for example, field effect transistors, may be used as well. It may likewise be readily understood and appreciated that while a positive drive pulse is used for purposes of illustration, a negative drive pulse and switching devices of the appropriate polarity may be similarly used.

Words 1 & 2 are connected to the N (i.e. 36) nozzles of the recording head in an interleaved fashion as shown, for the first 2XN"' (i.e. 12) connections. For the next 2XN' ,J connections, the words are again interleaved, but Word 2 is advanced two positions, i.e. a sequence of W, X, Y, Z, U, V in this example. Similarly, the following 2XN'" connections are again interleaved, with a further advance of Word 2 to Y, Z, U, V, W, X. Each nozzle is addressed by (driven by) its adjacent conductors. Nozzle 15, for example, is addressed by conductors B &. X, and will be fired only when B is high and X is low, or vice versa The advance of one word with respect to the other by two positions provides a unique address for every nozzle. Word 1 will have just one bit high at a time, while the other bits are open Word 2 may have any number of low bits at once, as is appropriate for the pattern to be printed For example, in Fig. 5, Word 1 has bit B high (indicated by "H"), and all other bits open (indicated by "X"). Word 2 has U, X, & Y held low (indicated by "L"), and V, W, & Z open ("X"). Only those nozzles defined by conductors B & U, B &ι X, and B & Y will fire, as shown. Alternatively, Word 2 may have just one bit low at a time, while the other bits are open, while Word 1 has any number of bits high at once, as is appropriate for the pattern to be printed As a further alternative, Word 1 may have just one bit high, and Word 2 may have just one bit low, so that just one nozzle is fired at any one time

In the manner described a total of just 2XN' electrodes and drive switches are necessary to control a recording head having N nozzles. Connections between the 2XN' /i electrodes, and the N conductors, can be made according to Fig. 5 by, for example, conventional printed circuit techniques as are well known. Substrate 12 may, for example, be comprised of a multilayer printed circuit board for this purpose.

A further consideration, where the pressure generating element 14 is an exothermic thin film, is to provide means to regulate the temperature of the element. In apparatus according to the prior art, variations in the amount of energy applied to an exothermic pressure generating element cause deviations in ink drop trajectories Energy variations may be due, for example, to differences in resistance from one element portion to another, changes in resistance of a given element portion due to temperature, aging, or other factors, changes in driving source voltage or impedance, deviations in driving source pulse width, or other factors. In addition, element portion temperature will vary as a function of ambient temperature and time elapsed since the last energization of the element portion. According to

the prior art, operation of the recording head at too high a frequency (1 e too little elapsed time between energizations) can result in permanent damage to the head

One method of protecting the individual element portions from damage due to too high an operating frequency is to adjust the drive source energy in response to operating frequency based upon the thermal time constant of the element portion If the elapsed time since the last energization of a particular element portion exceeds some time t, the temperature of the element portion is assumed to be at ambient, and a drive pulse of some energy calculated to raise the element portion to proper operating temperature is applied If the elapsed time is somewhat less than t, the element portion is assumed to have not cooled to ambient, and a dπve pulse of somewhat reduced energy is applied If the elapsed time is much less than t, the element portion is assumed to have cooled very little, and a dπve pulse of greatly reduced energy will be applied This method requires a means of determining the interval between dπve pulses for each element portion and using that time interval to calculate how much energy should be applied with the next drive pulse This may be accomplished using a microprocessor or other control device using a suitable algoπthm In addition, some means of adjusting dπve pulse energy is necessary This may be accomplished readily by, for example, adjusting the width (duration) of the dπve pulse

By actually momtoπng the temperature of each individual element portion during a dπve pulse, it is possible to both protect the element from damage due to overheating, and regulate the temperature of each element portion, thus achieving supeπor control of ink drop trajectory If the material compπsing the exothermic pressure generating element 14 has a temperature coefficient of resistance which is non-zero in the region of the desired operating temperature, as is typical of most materials, then the resistance of the element portion at the desired temperature may be calculated If a dπve pulse of known voltage is applied to the element portion, then the unique current magnitude which will flow through the element portion only at the desired temperature can also be determined By sensing the actual element portion current and comparing its magnitude to that expected at the desired temperature, the dπve pulse can be terminated as soon as that desired temperature is reached In this manner the width of the dπve pulse is determined by the actual temperature of the element portion The element portion current may be readily sensed by using a sensing resistor and comparator as are well known

Alternatively, a drive pulse of known current may be applied, and a voltage corresponding to the desired element portion temperature may be calculated. In similar fashion to that described, the actual voltage may be monitored and compared with that corresponding to the desired temperature, with the drive pulse being terminated responsive to said desired temperature being reached

In another aspect of the present invention, the pressure generating element 1 may be an exothermic element comprised of a material having a positive and non-linear temperature coefficient of resistance such that element portion temperature is inherently regulated The required characteristics of this material must be such that an initial application of voltage will result in energy flow into the element portion such that temperature will rise at a desired rate, but as the desired temperature is approached, the resistance of the element portion must increase such that no further temperature rise will occur. The width of the drive voltage pulse may be fixed at any convenient duration which equals or exceeds the maximum needed to achieve the desired temperature. In this manner the temperature of each element portion is inherently regulated. Suitable pressure generating element materials include polycrystaliine ceramics as are well known and used in the fabrication of positive temperature coefficient (PTC) thermistors.

In still another aspect of the present invention, the pressure generating element 14 and conductors 16 may be protected from corrosion, and the ink protected from electrolytic action, by the application of a dielectric thin film of SiO 2 , Ta-O 5 , glass or the like to prevent electrical contact between the ink and electrically energized portions of the head

While the invention has been shown and described with respect to specific embodiments thereof, this is for the purpose of illustration rather than limitation, and other variations and modifications of the specific embodiments herein shown and described will be apparent to those skilled in the art within the intended spirit and scope of the invention as set forth in the appended claims. Accordingly, the patent is not to be limited in scope and effect to the specific embodiments herein shown and described nor in any other way that is inconsistent with the extent to which the progress in the art has been advanced by the invention.