US3611982A - Development electrode control apparatus - Google Patents

References Cited UNITED STATES PATENTS 7 9x487 10/1960 Giaimo, Jr. 118/637 UX 3,147,147 9/1964 Carlson 1 18/637 3,412,710 11/1968 Robinson. 118/637 3,416,494 12/1968 Hudson 1 18/637 3,424,131 1/1969 Aser et a1 117/17.5 X 3,430,606 3/1969 Pease et

a1

1 18/637 3,506,259 4/1970 Caldwell et al. 117/17.5 X

SHEET

1 OF 3 INVENTORS SAMUEL D. CORIALE NED J. SEACHMAN ATTORNEY PATENIED 01:11 2M SHEU 2 OF 3 mm mm I bow vm W l. km um mm X Q PATENTEUIJEI12 I971

SHEET

3 OF 3 v HQK DEVELOPMENT ELECTRODE CONTROL APPARATUS This invention relates, in general, to xerographic developing apparatus and, in particular, to apparatus for regulating the bias potential on a development electrode in respect to a reference voltage sensed on an exposed xerographic plate prior to the plates being developed.

Next subsequent thereto in the path of drum rotation is an exposure station B wherein a flowing light image of a stationary original is placed on the drum surface. Basically, the exposure station comprises an optical scanning and projecting assembly and a stationary transparent copyboard 14 adapted to support the original to be reproduced. A moving light source 15 is mounted below the copyboard and is arranged to move in timed relation with a lens element 18 to scan the original supported upon the copyboard thus creating a flowing light image of the original. The light image is projected by the lens through a folded optical system, including an

object mirror

19 and an image mirror 20, arranged to focus the light image on the bottom of the drum.

Positioned adjacent to theexposure station is a developing station C in which is positioned a

developer housing

22 having a reservoir area therein capable of supporting a quantity of two component developer material including negatively charged toner particles. A bucket-type conveyor 23 transports developer material from the lower reservoir area to the upper part of the developer housing where it is deposited in entrance chute 21. Any suitable drive means can be used to rotate the bucket conveyor in the direction indicated. As will be explained in greater detail below, the developer material moves downwardly in contact with the upwardly moving photoconductive drum surface through a completely electroded development zone wherein the latent electrostatic image on the drum surface is developed. The unused developer material pases from the development zone and is directed back into the reservoir area by means of

pickoff baffle

28. A toner container and dispensing

apparatus

26 is affixed to the developer housing and is adapted to add fresh toner material into the reservoir area in proportion to the amount of toner deposited on the drum surface.

An image transfer station D is positioned adjacent to the developing station. Individual sheets of final support material are fed seriatim into the sheet registering and forwarding apparatus, generally referenced by numeral 27, from either of two

supply trays

36 and 27. The individual sheets are properly registered and then forwarded into moving contact with the rotating drum surface and the developed electrostatic image transferred from the drum to the final support material by means of a transfer corotron 25. In operation, the electrostatic field created hy the corona discharge device electrostatically tacks or bonds the transfer material to the drum surface wherein the transfer material is caused to move in synchronous relation with the rotating drum surface.

A

mechanical stripper finger

28 is pivotally mounted in close proximity to the drum surface immediately downstream from the transfer station. The stripper finger is arranged to move between the copy sheet and the drum surface breaking the electrostatic bond holding the sheet to the drum and to direct the support material into moving contact with the bottom surface of a stationary vacuum transport 29.

A combination of heat and pressure energy is employed in the present apparatus to fix the xerographic image to the final support material. The image bearing support material is guided into the fusing assembly 33 as it is moved along the bottom surface of transport 29. Fuser assembly 30 comprises an upper fuser roll 34 and a lower fuser roll 35 arranged to coact to deliver a pressure driving force to a sheet introduced therebetween. A

radiant heat source

38 is positioned transverse to the lower fuser roll and applies heat energy to the surface of the roll. The roll, which is specially coated, stores the heat energy on its surface. As the rolls are rotated in the direction indicated, both heat energy and pressure energy are delivered by the roll into the imaged areas thereby fixing the image to the final support material. After leaving the fuser assembly, the now fixed copies are transported through a circular paper path, as illustrated in FIG. I, into a

catch tray

39 where the copy can be conveniently collected by the machine operator. 7

As previously noted, the two component developer material is first transported from the reservoir or storage area in

developer housing

22 and deposited in a hopperlike input chute 21 by means of a bucket conveyor system 23. A quantity of developer material is stored within the input chute and flows downwardly through a constrained opening 41 into the introductory region of

development zone

40. As illustrated in FIG. 2, the front wall of the development zone is formed by the

movable drum surface

10 while the rear wall is formed by a series of downwardly extended electrodes running transversely across the photoconductive coating on the drum surface. The electrodes are supported in spaced parallel relation to the drum surface by means of an insulating support frame 43 secured to the walls of the developer housing by any suitable means. The individual electrodes are separated from each other by

dielectric blocks

42 so that the rear wall of the development zone presents a substantially continuous surface to the developer material introduced therein. Although not shown, end seals are provided between the electrodes and the drum surface to substantially enclose the development zone thus providing a conduit through which the developer material gravity flows. The development zone extends from the introductory opening 41 opposite to the upper drum surface to a point well below the horizontal centerline of the drum.

The first electroded region through which a latent electrostatic image is transported is the region influenced by a

lowpotential electrode

45 physically located in the bottom of the

development zone

40. The term low potential, as herein used, refers to a potential which is lower that the background potential on the xerographic plate surface. This term is broad enough to include a grounded electrode or even a floating electrode. Because of the unique control features of the present developing apparatus, carrier beads which are properly toned for optimum development are flowing through this lower development zone. In this preferred embodiment, the low-potential electrode is placed at a ground potential so that an extremely strong force field is established tending to force the negatively charged toner particles toward the plate side of the development wne. At the same time, the electrode acts as a conventional development electrode to enchance the latent electrostatic force fields, particularly the force field associated with solid imaged areas, so that extremely rapid and efficient image development is produced in this region.

The next electrode positioned in the direction of drum rotation is the

main development electrode

46. The main development electrode is biased at a potential somewhere between the image potential and the background potential found on the plate surface and preferably at some predetennined level above the background voltage. When an imaged area on the drumsurface is transported through the main development electrode region, the force field associated with the imaged area, being of a higher magnitude than the electrode force field, predominates. The toner in the flow stream adjacent to the imaged surface is thus attracted into the imaged areas. However, when a nonimaged or background area is moved through the main developing region, the electrode force field dominates and the toner particles are pulled away from the plate surface towards the backside of the development zone. The developer material moving in contact with the nonimaged drum surface therefore tends to mechanically scrub the background areas to dislodge randomly dispersed, weakly held, toner particles from the plate. This dislodged toner, coming under the influence of the stronger electrode force field, is similarly attracted towards the electroded side of the system. As can be seen, the main development electrode, in effect, acts as a self-resulting device to either complete image development or to cleanup background areas in this region.

The now xerographically developed photoconductive surface next moves into the last development region in which an extremely strong toner attracting force field is produced by a

cleanup electrode

47. A biasing

source

44 is electrically connected to the cleanup electrode and electrically biases electrode at apotential greater than the image potential on the plate surface, preferably 300 volts above the image potential. The-bias potential is sufficiently high enough to attract an extremely heavy concentration of toner in the flow stream to the backside of the development zone. The carrier beads moving in contact with the plate surface become toner depleted and therefore are capable of both mechanically scrubbing and electrostatically scavenging unwanted background development from the plate surface. Here again, the strong electrode force field attracts random toner particles from the vicinity of the plate surface such that a clear well-defined developed xerographic image leaves the development zone.

As shown in FIG. 2,

cleanup electrode

47 is turned at a slight radium at the developer entrance 41 and extends outwardly and upwardly from the development zone to form the bottom wall of the input chute 21. The opposite wall of the input chute is formed by an electrically

isolated baffle

48 secured to the developer housing wall by suitable means. The lower end of the baffle has a lip formed thereon complementary to the turning radius of the cleanup electrode so that a unifonn opening 41 is provided through which the developer material enters the development zone in a relatively undisturbed flow.

Baffle

48 is placed at a ground or toner repelling potential which, when combined with the toner attracting force field of

electrode

47, forces a preponderance of the toner particles in the flow to the backside of the system. Because of the input chutes physical configuration and the strong electrostatic force field associated therewith, the formation of toner powder clouds in and about the introductory region to the xerographic development zone is minimized thus preventing unwanted background development from occuring. A strong toner concentration is thus established on the backside of the flow stream prior to the developer material entering the development zone so that relatively toner deplete beads initially contact the drum surface as it leaves the development zone.

A sensing

probe support housing

49 is secured in the machine frame and is positioned between the xerographic ex posure station and the developing station. The sensing probe 50 (FIG. 3) is seated within the support housing in juxtaposition to one end of the drum surface and is arranged to sense a narrow sample strip on the photoconductive surface near the edge of the drum.

A solenoid actuated

shutter

53 is slideably mounted within the guides provided in the upper portion of the support housing. The shutter is operatively connected to a solenoid SOL-l by means of a

crank arm

54. The crank arm is rotatably mounted upon a

pivot pin

55 and the pin secured in the body of the housing. The lower end of the crank arm is pivotally affixed to the

solenoid actuator arm

56 while the opposite end of the arm is similarly connected to a downwardly turned

dependent flange

58 formed in the lower part of

shutter

53. A

pin

57, passing through the upper part of the crank arm, rides in a vertically aligned slotted hole (not shown) formed in

flange

58 which permits the shutter to move in a horizontal direction as the crank arm is rotated. In operation, the solenoid is energized once curing each copying cycle. As illustrated in FIG. 3, energization of the solenoid pulls

actuator arm

56 upwardly causing the crank arm to rotate in a counterclockwise direction. whereby, the shutter is moved back exposing the sampling probe to the drum surface.

The machine logic system, generally referenced in FIG. 2, is arranged to generate a midscan trigger signal during each xerographic copying cycle. in practice, the signal is generated as the scanning lens 18 physically passes the midpoint of its programmed path of travel and the trigger signal is passed to the sample and hold

circuitry

51. A voltage indicative of the plate background voltage is sensed by the probe and this used to generate a continuous output control signal which is applied to a

variable power supply

52. The power supply is operatively connected to the

main development electrode

46 and regulates the electrode potential at a predetermined level above the background voltage on the plate.

The midscan trigger signal generated by the machine logic system has a pulse duration of approximately 0.5 seconds and recurrence of about 1.5 seconds between automatic copying cycles. initially, the trigger signal is sent to the sample and hold control circuitry where it is applied to input terminal 94 (FIG. 5). The signal taken passes to the base of

transistor

65 causing the transistor to fire. The transistor is held conductive for the duration of the trigger pulse signal and allows current to energize

shutter relay coil

66. With the shutter coil energized, the actuator arm of solenoid SOG-l (FIG. 3) is pulled upwardly causing the shutter to move back thereby exposing

probe

50 to the drum surface. At this time, the probe sees the background voltage on the sample strip and sends a voltage signal indicative of this voltage to a unity gain electrometer amplifier 8I. Any suitable electrometer amplifier commercially available through a number of manufacturing sources having a very high impedance can be utilized in conjunction with the circuitry of the present invention. The output of the electrometer amplifier is passed through two more amplifier stages 83 and 84 and then applied to a hold circuit comprised of a high-impedance unity gain,

amplifier

86 and a

capacitor

87. The signal, however, is initially prevented from passing to the hold circuitry by a normally

open contact

85.

As shown in FIG. 4, probe 50 basically comprises a

sensing element

92 which is completely surrounded by an

insulator

93. The insulator is preferably fabricated of a material which is electrically insensitive to changes in humidity and functions to maintain a high probe-to-ground resistance. A

conductive shield

91 is also placed around the insulator material and the output from the unity gain electrometer amplifier fed back to this shield. By maintaining the shield at the same potential as the electrometer amplifier output in this manner a bootstrap effect, is produced causing in probe shunt capacitance and reduces current leakage from

probe surface

92 to the surrounding electrical ground,

The midscan trigger pulse is also applied to the base of

transistor

60 which is in the control circuitry for opening and closing

contact

85. The trigger pulse causes the transistor to conduct and an output signal from the emitter side of the transistor applied to a

monostable multivibrator

61. The monostable multivibrator holds or delays the input signal for approximately 0.16 seconds during which time the shutter is moved to a fully opened position. The signal is then passed to a second

monostable multivibrator

62 which, upon receiving the delayed signal, produces an output pulse signal having a pulse duration of about 0.22 seconds. The output pulse from

multivibrator

62 is applied to the base of

transistor

64 causing the transistor to fire. Current is thus allowed to energize

coil

63. With

relay coil

63 energized,

contact

85, in the hold circuitry, is pulled to a closed position and the sample voltage applied across high impedance unity gain amplifier 86 (FIG. 4).

Closing

contact

85 causes two discrete occurrences to take place. First, as noted above, the sensed sample voltage is impressed across the high-

impedance amplifier

86

andsecondly capacitor

87, in the hold circuitry, is also charged to the sample voltage. Termination of the 0.22 second pulse signal closes the sample window by cutting off

transistor

64. The circuit to relay

coil

63 is now broken and contact 85 allowed to return to an open position. The initial sampled voltage, however, which is sorted on

capacitor

87, continues to be impressed across

amplifier

86. Because of the high impedance of the amplifier, a relatively constant output is maintained during the hold period until the subsequent reclosing of

contacts

85 provide a new sample voltage. This output voltage is applied to the power supply high-voltage operation amplifier 73 (FIG. 4) holding the power supply relatively constant during the short period the sample and hold circuit is waiting for the next sample signal.

If the voltage level of the next sample signal differs from that of the first sample,

capacitor

87 is allowed to recharge to the new potential through

contact

85 through the circuitry of

amplifier

84. The new samplevoltage is impressed across the high-

impedance hold amplifier

86 and the capacitor is now charged to the new voltage. At the end of the sample period, contact 85 is again opened and the hold circuit again waits for the next sample. As can be seen, the above arrangement makes it possible for the present apparatus to sense both increases and decreases in drum potential while at the same time continually generating a control signal for regulating the main developing electrode potential.

Further circuitry is also herein provided to reduce the electrical drift in the electrometer amplifier between sampling periods. As shown in FIG. 5, the trigger pulse is also applied to the base of

transistor

78 causing the transistor to conduct. A inverted output signal is sent from the collector side of the transistor to the first of a pair of series coupled

monostable multivibrators

74 and 75. Upon termination of the trigger signal,

monostable multivibrator

74 is activated to provide a pulse of duration of about 0.24 seconds. During this delay period, the shutter solenoid coil is deenergized and the shutter is allowed to fully close. The delayed signal is then passed to the'second monostable multivibrator 75 which produces an output signal having a pulse duration of approximately 0.24 seconds.

The output signal from

monostable multivibrator

75 is applied to the base of a

second transistor

79.

Transistor

79 transfers an inverted output signal to the gating network made up of

diodes

72 and 73. During normal machine cycling, the inverted signal is conducted through

diode

73 and transistor to provide a grounding signal for the

electrometeramplifier

81. This signal is applied to a gating arrangement (not shown) in the electrometer amplifier circuit which grounds the input circuit for the duration of the 0.24 second delay during which

time probe surface

92 senses the ground potential of the closed shutter. The very high-impedance input circuit of

amplifier

81 is thus provided with a zero potential reference for r the 0.24 second duration of this gate signal. In this manner,

amplifier

81 is provided with an accurate zero potential reference once during each machine cycle (l.5 seconds). Thus reference technique eliminates errors due to the long term electrical drift characteristics of

amplifier

81.

When a copy run is initiated, that is, when lens 18 scans an original on the platen, the trigger pulse is also impressed upon the base of

transistors

68 and 69, which are caused to conduct. The voltage developed at the emitter of

transistor

69 is applied to

diode

72.

Diodes

72 and 73 fonn a gate which will pass only the lower of the two input voltages to the base of

transistor

80, and thus to the gage of

amplifier

81. The reverse biased diode appears as a high impedance to the signal generated by

monostable multivibrator

75 and the signal thus passes through the diode gating network to

transistor

80. A

capacitor

71, located in the base circuit of

transistor

68 holds

transistors

68 and 69 conductive during the short period between copying cycles thus holding

diode

72 in a reversed biased condition during this period. In this condition, the 0.24 second gate pulse passes through

diode

73 and

transistor

80 to

amplifier

81 as previously described. However, inactivation of the scanning system for any extending period of time causes

capacitor

71 to discharge and

diode

72 passes a zero volt signal from the emitter of

transistor

69 to the base of

transistor

80.

Transistor

80 turns off at this time causing a grounding signal to be sent to the electrometer amplifier gate. As can be seem the electrometer amplifier is continuously grounded by the control circuit any time the machine is on except during the time copies are being produced and a continuous train of trigger pulses is arriving at point 94 (FIG. 5).

2. The apparatus of

claim

1 wherein said shudder is placed at a ground potential.

4. The apparatus of

claim

3 wherein the voltage sampled is the background voltage on the image retaining member.