|Publication number||US3769630 A|
|Publication date||Oct 30, 1973|
|Filing date||Jun 27, 1972|
|Priority date||Jun 27, 1972|
|Also published as||CA1004722A, CA1004722A1, DE2331803A1|
|Publication number||US 3769630 A, US 3769630A, US-A-3769630, US3769630 A, US3769630A|
|Inventors||Hill J, West D|
|Export Citation||BiBTeX, EndNote, RefMan|
|Referenced by (35), Classifications (12)|
|External Links: USPTO, USPTO Assignment, Espacenet|
Hill et a1.
INK JET SYNCHRONIZATION AND FAILURE DETECTION SYSTEM [111 3,769,630 Oct. 30, 1973 Primary Examiner-Joseph W. Hartary 751 Inventors: James D. Hill; Hugh E. Naylor, III; Kendal] gznald L. West, all of Lexington, ABSTRACT Individual ink droplets are formed at a nozzle, pro-  Asslgnee: Intel-natural Busmess Machmes pelled toward a record medium, variably charged by a corporaton Armonk, charge electrode, and deflected by deflection plates  Filed; June 27, 1972 for printing of characters. Droplets not required for printing are directed to a first gutter. The charges on  Appl. No.: 266,790 the droplets develop a current in the first gutter that is sensed in an electronic feedback loop for synchroniza- 52 0.5. CI. 346/75 tion of drop formation with p charging- An auxil- 51 rm. C1. G0ld 18/00 iary gutter is Positioned to receive drops during a  Field of Search 346/75; 317/3 checking interval when a relatively high charge is pplied to the unused drops. The relatively high charge 5 References Cited on the drops develops a much larger current in the UNITED STATES PATENTS auxiliary gutter that is easier to detect. If desired, synchronization can also be effected by using the auxil- 3,562,761 2/1971 Stone et a] 346/75 iary gutter. 3,596,276 7/1971 Lovelady 3,681,778 8/1972 Keur 346/75 6 Claims, 4 Drawing Figures t :j :f i 7 u F MASTER MACHINE M ,W
CLOCK 13 LOGIC 11 M l I CHARACTER GENERATOR lo 9 .L (52 44 46 ANALOG SWITCH Ajf (BUTTER "E l SELECTION) V i MOUNTING MEANS 45b MOVING MEANS PATENTEDnmo ms 3; 769.630
' SHEET 10F 2 "wmm" j T MASTER MACHINE 1 CLOCK LOGIC CHARACTER -a GENERATOR 4o ;SYN9.-EU. E: 'RAMP-i g 5 e2 SYNC -l 5 CONTROL CHEW/455i 4e 5 glim 5 i ANALOG SGTCH A 65 5 v I 54 I E I (GUTTER B 5 SELECTION) REFERENCE 52 g VLTAGE1 5 l i Y 55 I 60 COMPARATOR 0 O 0 Q o h 31 450391 35 2G v a i t r ,1 /39a CUTTER N01 L J L I 38 MQUNTlNG MEANS I b MOVING MEANS. SUPPLY is 5 27 200o'do oi GUTTER N0. 1
PAIENIEflnmamszs 3 9 6 SHEET ear 2 1011s I DROP TIME J L FIG. 3
NORMAL CHARGE ELECTRODE DRIVER SETTLING TIME ilfins f fius h "3.511s *3 -10 VOLTS 7 sum PULSE GUTTER N0.1 m VOUS s g 1o vous SYNC RAMP GUTTER N0.1 L--ov0us i 2$0 VOLTS 5 --2oovoLT SYNC RAMP GUTTER N0.2 5 w VOLTS r 5 v 5 --VOLTS CHECK|NGPULSEGUTTERNO.1 g; 1...
Y I -2oovous CHECKING PULSE CUTTER N0.2
SAFE AREA OF DROP FORMATION FIG. 4
5 L87. MASTER PR|NT|NG PRINT SIGNAL CLOCK. LOGIC (82 9e INK SUPPLY OR SYNC PULSE 85 INK SUPPLY REF VOLTAGE no a4 SYNC COUNTER DECODE CONTROL REGISTER SELECTOR INK JET SYNCHRONIZATION AND FAILURE DETECTION SYSTEM BACKGROUND OF THE INVENTION AND PRIOR ART -The following US. Pat. Nos. are representative of the prior art: Lewis, et al, 3,298,030; Keur, et al, 3,465,350; Keur, et al, 3,465,351; Lovelady, et a], 3,596,276; and Sweet 3,596,275.
The Lewis, et al, patent describes drop synchronization using a phase shifter to insure proper charging of drops at the correct time. The Keur, et al, U.'S. Pat. No. 3,465,350 describes the use ofa video pulse that is applied to the ink drops, and if the phase is correct, a drop detector is actuated to so indicate. The Keur, et al, U.S. Pat. No. 3,465,351 also makes use of a drop detector in various arrangements. The Sweet patent describes ink jet writing apparatus incorporating means for variably charging the drops and maintaining a constant potential on the deflection plates. The Lovelady patent illustrates a form of servo loop for controlling the phase of the charging voltage and making use of a drop catcher.
None of the foregoing art describes a system like the present system making use ofa pair of drop catchers or gutters and the development of relatively high currents and signal levels not normally encountered. in the sys- -tem during printing of characters.
SUMMARY OF THE INVENTION A In accordance with the present invention, a system incorporates means for producing ink drops as a stream of drops, facilities for variably charging the droplets in accordance with information or for synchronization and checking purposes, deflectionmeans for deflecting the variably charged drops toward paper or either one of a pair of gutters, in dependence upon the amount of charge on thedrops, and circuitry for detecting proper phasing or synchronization of drops with respect to charging and formation of drops, as well as failure detection. In its various forms, the invention contemplates an electronic servo or feedback loop operable in a real time fashion to maintain proper synchronization.
In one version, a counter means is advanced until a change current above apredefined level is found. The synchronization procedures are combined in one embodiment with a failure detection capability making use of a second gutter that receives drops when properly phased and that develops higher currents that are easier to detect. The second gutter may also be used for synchronization purposes if higher charge potentials are applied.
OBJECTS Accordingly, a primary object of the present inven-, tion is to provide a system for ink jet printing apparatus to determine proper synchronization of drops formed in the system.
Still another object of the invention is to provide a system having synchronization and failure detection ca-' tablished to check proper drop formation and phasing.
Another object of the invention is to provide a system that is operable to detect loss of electric field, loss of charge voltage, and related failures in an ink jet apparatus.
Another object of the invention is to provide monitoring of an ink jet system while printing, between characters or while in the home position etc., by means so as to immediately detect a failure in synchronization.
A further object of the present invention is to enable synchronization on a line-by-line basis, as when the printing means is at a home position, or between characters during actual printing operations, or within the matrix boundaries of an individual character when unused drops are available for checking purposes.
The foregoing and other objects, features, and advantages of the invention will be apparent from the following more particular description of the various embodiments of the invention as illustrated in the accompanying drawings.
IN THE DRAWINGS FIG. 1 is a diagram of an ink jet printing system incorporating the synchronizing and checking techniques of the present invention and particularly including a pair of gutters, and various circuitry controlling printing, synchronizing, and checking.
FIG. 2 is a modified comparing arrangement for use i in the circuit of FIG. 1.
DETAILED DESCRIPTION Ink Jet Printing System The system of FIG. 1 is primarily intended for printing of intelligence, such as characters or symbols on a record member, such as a sheet of paper 1, by formation, propulsion, charging, deflecting, and deposition of ink drops 2 on paper 1, supported by means 4. The drops move in a stream or streams at high speeds from a source' 3. Ink from an ink supply 5 is directed by means of pump 6 to source 3 which incorporates a vibrating means, such as a piezoelectric crystal 8 and an associated nozzle 10. A master clock 11 provides basic timing pulses to the system including machine logic 13 and a character generator block 14. Crystal 8 is driven at the frequency provided by clock 11 under control of crystal driver 15.. The frequency may be a very high range such as kilohertz, or more. Pulsation by crystal 8 effects formation of individual droplets that are directed through the center of a charge electrode 18 as is known in the art. Characters on paper 1 may be formed as a matrix of droplets, for instance, 24 droplets wide by 40 droplets high. In order to control the placement of drops on paper 1, a varying amount of charging voltage is provided to charge electrode 18 from charge electrode driver 21. Individual drops are directed between deflection plates 22 and 23 having a high potential, such as 3,000 volts, supplied from terminal 25. As is taught in the art, the arrangement is such that a constant potential exists between plates 22 and 23 which when combined with the variable charging on drops 2 effects selective displacement of the drops in a vertical sense, for example, to any one of the 40 possible positions in the, matrix. Unused drops are directed either to gutter No. 1, designated 35, or togutter No. 2, designated 36, as will be described in greater detail. These drops are returned by lines 27-and 27a under control of pump 30 to ink supply 5. The proper voltage applied to drops 2 by charge electrode 18 from driver 21 during printing of characters is'supplied by line 32 from character generator 14. Ordinarily, a single vertical column of drops is propelled toward paper 1 with selective deflection onto the paper at appropriate positions or into one of the other-of the gutters 35 or 36. Source 3 and elements 8, .10, 18, 22-23, 35 and 36 are customarily mounted on a mounted means 37 interconnected with said elements bydashedlines 39a and 3922. Formation of a plurality of columns in a horizontal direction, such as the exemplary number of 24 is effected by relatively moving paper l and source 3, as well as electrodes 18, 22, and 23 in a timed fashion to achieve a side-by-side arrangement of columns, as by moving means 38 interconnected to mounting means 37 by line 45a and to support means 4 by line 45b. Such movement may be effected on an incremental basis or on a continuous basis. In this manner, entire lines on a document are printed. Ordinarily, at the end of each line of printing, the ink drop generating and deflecting means is relatively displaced with respect to paper 1 to a home position in preparation for a succeeding line. At the home position, as well asbetween characters, during actual character formation and while returnin g'to home position, the various synchronizing and checking procedures set forth herein may be employed to control drop formation, and the-relative timing of charging by electrode 18 with respect to individual drops passing through electrode 18. v V
AUTOMATIC SYNCI-IRONIZATION OF DROP SEPARATION AND CHARGE VOLTAGE A In a synchronized pressure ink jet system of the type described herein, the-drop breakoff and charge voltage timing must by synchronized. This requires thatthe charge voltage applied by electrode 18 shall have ment of ,drop formation time with respect to drop charging through an electronic feedback loop.
*At anytime when drops 2 are not being used to print characters on paper 1, such as atthe home position, between characters, or during deflection of drops on a column by column basis, a sampling function'is performed. Thus, synchronization can take place any time that printing is not taking place.
Reference is made to FIG. 3 that shows typical time intervals and pulse wave forms during a single drop time, assumed to be 10 microseconds in duration. The first portion of the total of i microseconds, that is, 2.5 microseconds, is set aside to allow the driver time to reach the proper charging voltage. The remainder of he. rqp ti srthat sr .7.- Iin !999nd. m-gr ized as the safe area of drop formation. Accordingly, a drop formed any time during this interval should be properly charged and deflected as it is propelled toward paper 1.
SYNCHRONIZATION WITH NARROW PULSES GUTTER NO. 1
Several wave forms are of interest in FIG. 3. As one example, a series of narrow pulses on line 41 may be directed to driver 21 under controlled conditions. Sync control 40 adjusts driver 15 voltage through a range of values until the narrow pulseseffect charging of drops 2'. During synchronization using gutter No. 1, pulse signals are applied from Sync Control block 40 by line 41 to charge electrode driver 21 and ultimately to charge electrode 18. As shown in FIG. 3, a typical pulse voltage range is from 0 volts to volts. Machine logic 13 by line 44 switches analog analog switch 46 to receive an input only from gutter 35 on line 47 designated A." Ordinarily, a sequence of drops moves into gutter No. 1 designated 35 developing a currentzof some level directly proportional to the amount of charge on a series of'individual drops. Such a series may comprise a portion of a column of unused drops or several such column s, depending on system sensitivity. Means, known in the art, are mounted in association with gutter N o. l to provide a current level on line 47 corresponding to and directly related to the charge levels on drops 2 going into gutter No. 1. As an example of one possible configuration, for every two volt difference potential applied onto a series of drops 2 by charge electrode 18, approximately one nanoampere of current is derived on line 47. If for example", drops in a series were charged by 10 volts on the charge electrode, on average, then 5 nanoamperes is available on line 47. The output of switch 46 is directed to a drop charge amplifier 50 that converts the current levels to a usable voltage level. The output of amplifier 50' is directed by line 30 52 along with reference 'voltage from source; 54 on line 55 for comparison in a comparator circuit 57. The output of comparator 57 on-line 60 isdirected to Sync Control 40 which concurrently is supplying a series of stepped driving voltage levels by line 62 to crystal 3 driver 15, thereby adjusting the timing of drop separationand maintainingthe time of drop separation in a desired relationship with respect to the potential applied by driver2l. Synchronization is attained when charged drops are first detected. It is also possible to synchronize with narrow pulses using gutter No. Zdesignated 36. Y l
* SYNCI-IRQNIZATION WlTI-IRAMP SIGNAL Y i ,HGUYTTER Nor 1 As a preferred alternative, a ramp signal ranging from 0 to l0volts is provided .by line.42 to driver 21.
Synchronization is attained using gutter No. '1 desig electrode 18. Machine logic 13 by line 44 switches analog switch 46 to receive an input only from gutter 35 on line 47 designated A. As before, a sequence of drops moves into gutter No. 1 designated 35 developing a current of some level directlyproportionalto the amount of charge on a series of individual drops. Such a series may also comprise a portion of a column'of unused drops or several such columns, depending on system sensitivity. A current level is developed on line 47 corresponding to and directly related to the charge levels on drops 2 going into gutter No. 1. The current level will depend upon the time of drop breakoff during the ramp signal interval. In this case, as before, the output of switch 46 is directed to a drop charge amplifier 50 During synchronization using gutter No. 1, the signal is applied from'Sync Control block 40 by line 42 to charge electrode driver 21 and ultimately to charge SYNCHRONIZATION WITH RAMP SIGNAL GUTTER NO. 2
Gutter No. 2 designated 36 in FIG. 1 may also be used'for' normal drop synchronization of phasing, if desired. A synchronization pulse using gutter No. 2 is illustrated as a ramp wave form in FIG. 3, and is supplied on line 81 from Sync Control 40 to driver 21. Such checking with gutter No. 2 is evidence that proper character height is being maintained. This may also be pulse may, for example, be in the range of 200 to 250 7 volts. It is noted that a greater change that is, 50 volts, occurs in this case than in the case 'of synchronization using gutter No. l, where only a 10 volt change occurs. The greater rate of change whensynchronization is effected with gutter No. 2 provides a much higher level of current that is easier to detect in the circuits.
In any of the foregoing instances, if a sufficient series of drops 2 passes through the selected gutter, a current in nanoamperes is developed that is detectable. Amplifier 50 convertsits input current level to low impedance voltage level. If a ramp is used, and, as an example, reference voltage supply 54 indicates 5.0 volts as a desired voltage level, and amplifier 50 provides a 7.5 volt level to co.mparator.57, a corrective signal is developed on line 60 to change thedrive voltage applied by driver under control of Sync Control 40 in order to more closely achieve the 5.0 volt level. It is somewhat impracticalto attempt to sense the current levels developed by a single ink drop aswould be done in a 100 percent servo system. Thus, a series of drops is integrated to develop the'necessary current levels. Such a series of drops would be available, as an example, when an entire column of droplets or most of the droplets in a column are available during printing of characters of symbols.
The foregoing synchronization procedures and feedback circuit's are gated on by machine logic 13 during any non-printing time, as desired, and may occur when the machine is first turned on, when the first character is printed, in between characters, in between lines, etc.
USE OF CHECKING PULSE GUTTER NO. 1 A checking pulse may be applied on line 43 ha low voltage range such as 0l0 volts which when sensed by current levels on line 47 can determine various system failure, such as drop charging failure, loss of synchronization, etc. However, for a'most complete check, gutter No. 2 is preferably used.
USE OF CHECKING PULSE AND SYSTEM FAILURE DETECTION USING GUTTER NO. 2
done while printing is taking place whenever unused drops occur. When in checking mode B," machine logic l3 forces switch 46 to pass current only from input b connected to gutter N0. 2, 36, by ling 74. As an example, a sequence of drops in a given series of drop intervals could be sufficient to develop adequate current on line 74.
. The 10 volt level used for synchronization into gutter No. l develops a gutter current on line 47 in the range of 4 to 6 nanoamperes. A greater charge level required to deflect drops 2 up to gutter 36 achieves a higher current level that is easier to sense by circuits 46 and 50.
If, for example, volts deflects drops 2 to the upper portion of paper 1 during printing of chaacters, to 200 volts applied to unused drops can deflect those drops to gutter 36. Such voltage levels develop current levels in gutter 36 and on line 74 in the range of 90 to 100 nanoamperes which is about 20 times the current levels developed on line 47. It is apparent that the higher 'current levels are more readily sensed and worked with in the circuits as shown.
The advantage of the checking pulse applied over a number of drop intervals is that the system can determine whether proper synchronization is being maintained, whether the charge electrode and driver are op erating properly, whether the high voltage from terminal'2'5 is present and of course, whether other components in the system are working properly. The checking pulses are applied by line 65 to driver 21 in order to produce the required currents in gutter 36. These may be compared by comparator 57- against reference voltage from block 54 with suitable changing of reference level on line 77 from Sync Control 40.
A possible approach using this technique is for machine logic 13 to determine the maxium number of drops used during printing of characters and thus also determine the minimum'number of drops that should be available for gutter No. 2 during normal printing. Such minimum number of drops should result in a particular current level on line 74 which is measured by circuits 46 and 50 and compared at comparator 57 with a threshold level from block 54. If such minimum potential is not available, a failure is indicated to machine logic 13 on line 80. The machine logic can then take steps to turn off the crystal drive from driver 15-, to turn off driver 21, deactivate pumps 30 and 6 and take any othersteps necessary to minimize the amount of ink that is sprayed on paper 1 or other parts of the mechanism.
The foregoing techniques result in less costly measuring circuitry and-less-noise sensitive signals. An important advantage of the checking procedure is that the logic 13 is able to continually monitor the performance of the ink jet mechanism, if desired.
ALTERNATIVE CHECKING CIRCUIT FIG. 2 illustrates an alternative checking circuit having various members 35, 36, 46, 47, 50 and 74 corresponding to those similarly numbered members in FIG. 1, but having a comparator 57a and an independent second reference source 54a that is based strictly on a go-no-go basis. The analog switch 46 monitors drops Zimpinging on gutter No. 2 (36) and essentially determines if the drops are present or absent. Reference voltage 2 from source 54a establishes a threshold level for comparator 57a and the output from amplifier 50 should always exceed such level. If it does not then a signal is provided by line 80a to indicate a machine failure.
to decode selector 84, on line 85 to printing logic 86 and on line 87 to circuit 88. Sync time is indicated by printing logic 86 on lines 90 and 91 that are directed to Sync Control 40a and And circuit 88, respectively. The circuit includes a crystal 95 receiving ink on line 96 from an ink supply, not shown, a nozzle 98 and a crystal driver amplifier 99. Amplifier 99 drives crystal 95 to form drops 100 that pass through charging electrode 102 driven by charge electrode driver 104. Driver 104 in turn is driven from Or circuit 88. Individual drops are deflected to paper 1, for printing or to gutter 106 when not used. The circuit includes a counter register 110 that serves during normal printing times to define the crystal driver signal.
During synchronization time, Sync Control 40a advances counter'register 110 until a charge current above a predefined level is found. This is done by detection of current levels in gutter 106, supply of such levels on line 112 to amplifier (AMP) 50, conversion of such levels to voltage levels amplifier 50 and comparison of such levels with reference voltage from terminal 113 by comparator (COMP) 114. The output of comparator 114 is directed to Sync Control 40a. When a charge current above a predefined level is recognized, the value in counter 110, is held. This maintains the drive level from amplifier 99 until the next synchronization time. Counter register 110 outputs are decoded by block 84 which in turn is driven from master clock 82. The individual clock signals each have a different phase relationship with respect to the synchronization pulse on line 87. If Sync Control block 40a is unable to find a signal which provides synchronization it will so indicate by line 115 to printing logic 86 thereby evidencing a synchronization failure. The Sync-Control logic contains a delay-to. compensate for the transit time ofthe drops.
The sync time signal produced by the printing logic 86 controls gate 88 so as to allow only printing signals to go to the charge electrode driver dring printing and allow only sync pulses to reach the charge electrode driver 104 during synchronization.
While the invention has been particularly shown and described with reference with several embodiments, it will be understood by those skilled in the art that various changes in form and detail may be made without departing fr m he spiri a d.299P 9f,th.. n.vsmi9n- 'What is claimed is:
1. An ink jet printing system for printing on a record mediumby ink drop deposition, comprising: means for supporting said record medium .at a printing station; means for forming and propelling ink drops toward said record medium; i cyclically operable means operable in timed relation with said forming and propelling means for charging and deflecting a plurality of said drops on a selective basis to form visible indicia upon said rec qm s har n .s qifl sflife,
being operable to charge and deflect said drops in a range from a relatively low to high potential with the extremes of said range representing drops not required for printing; first gutter means positioned in the path of travel of a first type of unused drops charged at said relatively low potential to collect said first type of drops said first gutter means providing a relatively low synchronization current from charged drops travelling in said first gutter means second gutter means positioned in the path of travel of a second type of unused drops charged at said relatively high potential to collect said second type of drops said second gutter means providing a relatively high checking current level; from charged drops travelling in said second gutter means; amplifier means interconnected with said first gutter means for providing a low synchronization potential responsive to the relatively low synchronization current provided by said first gutter means, and further interconnected with said second gutter means for providing a high checking potential responsive to the high checking current level from said second gutter means; character generating means for activating said charging and deflecting means in a printing range within but not including said relatively low and relatively high potential in order to deflect selected ones of said drops within a printin range on said record medium; synchronization means operable to activate said charging and deflecting means at said relatively low potential in order that low synchronization potential is developed by said amplifier means; checking means operable to activate said charging and deflecting means at said relatively high potential in order that the high checking potential. is developed by said amplifier means; comparing means for comparing said synchronization potential with predetermined'reference levels representative of correct synchronization in said systemyw means controlled by said comparing means for main- A taining correct phase between drop formation and charging; said comparing means comparing said checking potential with predetermined reference levels representative of correct operation of said system; and output means from said comparing means for indicating a failure of said system. 2. The system of claim 1 further comprising: means mounting said forming and propelling means, said charging and deflecting means and said first and second gutter means in a unitary structure adjac ent said record medium; means operable in timed relation to drop propulsion toward said record medium for relatively moving said mounting means and said record medium from a home position in order to form matrices arranged in lines printed intelligence on said record medium each of said matrices comprising a set of vertical columns and horizontal rows of drop locations and each of said matrices being separated from a preceding or succeedingmatrix by an inter-matrix gap. 3. The system of claim 2 wherein:
said synchronization control means provides synchronization pulses when said mounting means and said record medium are relatively positioned at home position; and
checking pulses any time during relative movement when drops are not required for printing.
4. The system of claim 1 further comprising:
an analog switch responsive .to current levels from said first sensing means when activated in a first mode and to current levels from said second sensing means when activated in a second mode;
selection means for selecting said first and second modes of said switch on a selective basis;
amplifier means responsive to current levels from said analog switch to developpotentials therefrom, and
means connecting potentials from said amplifier means to said comparing means.
5. The system of claim 1 further comprising:
a charge electrode and charge electrode driver asso- 10 ciated with said drop charging and deflecting means;
a crystal and crystal driver associated with said drop forming and propelling means; and
means applying synchronization and checking signals from said synchronization control means to said charge electrode through said charge electrode driver;
means'for applying output signals from said first comparing means to said synchronization control means;
and means in said synchronization control means for developing and applying correction signals to said crystal through said crystal driver in order to maintain in proper phase.
6. The system of claim 1 further comprising:
means responsive to a failure detection signal from said comparing means to de-activate said system.
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|U.S. Classification||347/80, 347/90|
|International Classification||B41J2/115, B41J2/185, B41J2/12, H04N1/23, G06K15/10|
|Cooperative Classification||B41J2002/1853, B41J2/115, B41J2/185|
|European Classification||B41J2/115, B41J2/185|