DE3788833T2 - REGULATING THE LOAD DISTRIBUTOR OF A LIQUID DEVELOPER. - Google Patents

Description

Background of the invention

Liquid developers generally contain a liquid phase comprising an insulating carrier liquid, such as an isoparaffin hydrocarbon, and a solid phase comprising toner particles consisting of a pigment and a binder. The solid phase toner is dispersed or suspended in the liquid phase carrier. Liquid developers also contain a small amount of charge director which ensures that the toner particles are uniformly charged with the same polarity, which may be either positive or negative depending on the particular application. The liquid developer is used to develop a latent image formed on a photoconductive imaging surface. Usually, the photoconductive surface is charged with one polarity; and the toner particles are charged with the opposite polarity. If the liquid developer contains too much charge director, the developed images tend to be somewhat weak because of image charge losses due to leakage into the liquid developer with the higher conductivity. On the other hand, if the liquid developer contains insufficient charge director, the developed images tend to be somewhat weak because the toner particles with reduced charge move at a reduced speed through the developer liquid to the image forming surface.

An even more serious problem with liquid developers with insufficient charge director is that the toner tends to come out of suspension, creating sludge deposits that grow steadily until the electrostatic copier has to be stopped for cleaning. By maintaining Due to the charging of the toner particles by the charge director, the toner particles repel each other, remain dispersed and are prevented from clumping together and forming sludge deposits.

Summary of the invention

In general, our invention provides a liquid developer control system in which a liquid carrier, such as isodecane, is added from a first container to a dilute working developer suspension to maintain the volume of that working developer constant. The optical transmittance of the working developer is measured; and toner concentrate from a second container is added to the working developer to maintain its optical transmittance at a predetermined value. The conductivity of the working developer is also measured; and charge director concentrate from a third container is added to the working developer to maintain its conductivity at a predetermined value.

When making a copy with a liquid developer, a constant amount of carrier liquid is applied to the entire surface of the copy sheet. This carrier liquid from the working suspension contains an associated amount of liquid phase charge director. Furthermore, an amount of toner is applied to the copy sheet that corresponds to the amount of printing on the copy sheet. This toner contains an associated amount of solid phase charge director. Accordingly, during the production of a copy from the working developer, a first constant amount of charge director belonging to the carrier liquid is lost, as well as a second variable amount of charge director belonging to the toner solid particles. The toner concentrate in the second container is preferably provided with a total amount of charge director that does not significantly exceed that belonging to the solid phase toner. This prevents detectable sludge deposition of the toner concentrate and ensures that the toner concentrate does not cause an increase in the conductivity of the working developer beyond the desired value. The charge director concentrate from the third container effectively supplies the charge director lost through transfer of carrier liquid to each copy sheet.

An object of our invention is to provide a liquid developer control system in which a charge director concentrate is added to the working developer suspension in response to a conductivity measurement of the same.

A further object of our invention is to provide a liquid developer control system in which a toner concentrate is supplied to the working suspension in response to a permeability measurement thereof.

Another object of our invention is to provide a liquid developer control system in which the toner concentrate contains a total amount of charge director that does not significantly exceed that associated with the solid phase toner.

Another object of our invention is to shut down an electrophotocopying machine when the temperature of the liquid developer rises too high in order to prevent sludge deposition.

Another object of our invention is to shut down an electrophotocopying machine when the conductivity of the liquid developer falls significantly below its proper value in order to prevent sludge deposition.

Other and further objects of our invention will become apparent from the following description.

The state of the art

Gardiner et al 3,981,267 (Re. 30,477) uses a conductivity measurement of the liquid developer to control a constant current source that supplies a bias current to the developing electrode.

Mochizuki et al 4,310,238 presents a liquid developer permeability control system in which the desired permeability value is changed by measuring the conductivity of the working suspension. That is, as many copies are made, as the conductivity of the working suspension gradually increases, the resulting "fatigue" of the developer is compensated for by adding more toner concentrate to reduce the permeability of the working developer.

Short description of the drawing

The accompanying drawing, which forms a part of and is to be read in conjunction with this specification, is a schematic view of a preferred embodiment of our liquid developer charge director control.

Description of the preferred version

In the drawing, the working suspension is contained in a tank 10. A first container 12 having a neck 24 contains a supply of carrier fluid, such as Isopar-G (a trademark of Exon Corporation), which is a mixture of isoparaffin hydrocarbons, mostly isodecane, having an extremely low volume conductivity. Container 12 is mounted inverted; and carrier fluid exits neck 24 until the level of the working suspension in tank 10 reaches the lower end of neck 24. The working developer is relatively dilute and can typically consist of 1% toner solid particles and 99% carrier liquid by weight.

A second tank 14 contains a supply of toner concentrate. The toner concentrate typically consists of 10% toner solids by weight and 90% carrier liquid, such as Isopar. The rate of sludge deposition depends on temperature and the amount of charge director. Sludge deposition increases with increasing temperature and is reduced by charge directors. Sludge deposition of the toner concentrate in tank 14 can be neglected compared to that of the working slurry in tank 10 since the concentrate is essentially at ambient or room temperature or only slightly above that, whereas the working slurry in tank 10 can reach temperatures up to 100ºF. Any localized heat zones in tank 10 will constitute sludge deposition sites.

In order to further reduce any minimal sludge deposition of the toner concentrate in the second container 14, the toner concentrate is further provided with a relatively large amount of charge director, which however does not significantly exceed that associated with the solid phase. Both toner solid particles and associated charge director are removed from the system by transfer to copy paper and also by sludge deposition. Carrier liquid can be removed from the system both by transfer to copy paper and by evaporation. Both carrier liquid and associated charge director are removed from the system by transfer to copy paper. However, the evaporation of carrier liquid does not result in a loss of charge director. If the copier is kept at operating temperature for a long period of time and the sludge deposition and evaporation rate are caused solely by toner concentrate from the second container 14, the amount of charge director in tank 10 continuously increases. when the toner concentrate contains charge director in excess of that associated with the toner solid particles. We ensure that the charge director control system does not fail due to excess charge director in tank 10 by ensuring that the charge director in the toner concentrate does not significantly exceed that associated with the toner solid particles.

A third container 16 contains a charge director concentrate, which can contain 5% by mass of charge director and 95% by mass of carrier liquid, such as Isopar.

Electrophotocopiers use a photoconductive surface that can be either positively or negatively charged. The charge director imparts a charge to the toner particles that is usually opposite to that with which the photoconductive surface is charged. For example, if the surface is positively charged, a negative charge director would be used in both the toner concentrate container 14 and the charge director concentrate container 16. Such negative charge directors include metal salts of fatty acids, such as calcium palmitate, and metal salts of naphthenic acid, such as barium petronate. If the photoconductive surface is negatively charged, a positive charge director would be used. Such positive charge directors include transition metal salts of fatty acids, such as aluminum stearate, and transition metal salts of naphthenic acid, such as cobalt naphthenate. Other charge directors known in the art include sodium dioctyl sulfocinate, lecithin and calcium petronate, also known as "mahogany soap". In general, we prefer charge directors that are soluble in the carrier liquid.

A shaded-pole asynchronous motor 18 drives an agitator 19 in tank 10 to ensure the settling of toner in the working suspension to prevent settling of the toner in the concentrate. A further shaded pole asynchronous motor 20 drives an agitator 21 which extends through a hole 26 in the top of the second container 14 and prevents settling of the toner in the concentrate. The charge director concentrate container 16 is provided with an air hole 28 at the top thereof. The second container 14 is provided with a short outlet pipe 30 which is connected via a flexible pipe 34 to the inlet of a positive displacement pump 38 having an eccentric shaft 39 driven by a DC motor 40. The outlet of pump 38 is connected via a flexible pipe 46 to a short supply pipe 50 from tank 10. The third container 16 is provided with a short outlet pipe 32 which is connected via a flexible pipe 36 to the inlet of a positive displacement pump 42 having an eccentric shaft 43 driven by a DC motor 44. The outlet of pump 42 is connected by a flexible conduit 48 to a short supply pipe 52 from tank 10. Positive displacement pumps 38 and 42 may be of the flexible vane type; and both the rotor thereof and motors 40 and 44 rotate counterclockwise in the direction of the arrows. Power to motor 40 drives pump 38 which supplies toner concentrate from container 14 to tank 10. Power to motor 44 supplies charge director concentrate from container 16 to tank 10.

One wall of tank 10 is provided with a transparent plate 62 whereby light from an incandescent lamp 60 can pass through it onto a photosensitive device 66 mounted in tank 10. Device 66 may comprise a photoconductor such as cadmium sulfide. The toner control may be substantially the same as that described in application Serial No. 296,970 filed August 27, 1981 for an Improved Toner Control System, now Patent 4,579,253. Light from lamp 60 is also directed through a variable or adjustable aperture 64 onto a reference photosensitive device. 68, which resembles device 66. The primary winding 56 of a transformer, generally designated by the reference numeral 54, is energized by a source of alternating current of, for example, 115 volts. Transformer 54 is provided with a secondary winding 58 having a grounded center tap. Terminals 57 and 59 of winding 58 produce +10 and -10 volts alternating current, respectively. Lamp 60 is connected between terminals 57 and 59. Terminal 57 is connected through device 68 to one terminal of a potentiometer 67, the other terminal of which is connected through device 66 to terminal 59. The wiper of potentiometer 67 is connected through an alternating current amplifier 80 to the input of a phase sensitive detector 84 which receives a reference input from terminal 59. Positive outputs of detector 84 operate a trigger circuit 86 which turns on a free-running power multivibrator 88. Multivibrator 88 is connected to one terminal of motor 44, the other terminal of which is grounded.

Terminal 57 is connected to one electrode 70 of a pair of spaced electrodes 70 and 71 located in tank 10. Electrode 71 is connected through a 50 megohm resistor 74 to the wiper of a 200 kilohm potentiometer 73 connected between terminal 59 and ground. Terminal 59 is connected to electrode 71 through a variable capacitor 72 rated at 35 picofarads. Terminal 59 is further connected in series through a variable resistor 76 rated at 33 kilohms and a 0.07 microfarad capacitor 77 to ground. Electrode 71 is connected to the gate of an insulated gate field effect transistor amplifier 81 which may include a source follower having a voltage gain substantially equal to unity and an extremely high input impedance and a low output impedance. The source output of field effect transistor amplifier 81 is connected via an AC amplifier 82 is connected to phase sensitive detector 83, the reference input of which is fed through a conductor 78 connected to the junction of variable resistor 76 and capacitor 77. Detector 83 controls the positive input of a unity gain differential amplifier 85. Positive outputs of amplifier 85 operate a trigger circuit 87 which turns on a free running power multivibrator 90. Multivibrator 90 is connected to one terminal of motor 44, the other terminal of which is grounded.

A power plug 92 provides a 115 volt AC power source at 60 hertz. Conductor 93 of plug 92 is connected to one terminal of primary winding 56 and to the armature of a normally closed relay switch 105 which can be opened by energizing a DC relay winding 104. Conductor 93 is also connected to one terminal of each of the agitator motors 18 and 22. Conductor 91 of plug 92 is connected to the armature of a normally open relay switch 99 which can be closed by energizing an AC relay winding 98. The fixed contact of relay switch 99 is connected to the other terminal of each of the agitator motors 18 and 22, the other terminal of primary winding 56 and through a resistor 102 to one terminal of relay winding 98. The other terminal of winding 98 is connected to the fixed contact of relay switch 105. Conductor 91 is connected to a contact of a spring-loaded, normally open "on" switch 94. The other contact of switch 94 is connected to the first terminal of winding 98 through a resistor 96. The fixed contact of relay switch 99 also supplies voltage to the copier, as is well known in the art.

Terminal 59 is connected to one contact of a spring-loaded, normally open "off" switch 108. The other contact of switch 108 is connected via a resistor 110 and forwardly connected through a diode 112 to a first terminal of relay winding 104, the other terminal of which is grounded. The output of amplifier 85 is connected through a normally closed, manually operated switch 114 and forwardly connected through a diode 115 to the input of a trigger circuit 116. The output of trigger circuit 116 is connected to the first terminal of relay winding 104. As each copy is made, an output is produced by circuit 118 which is fed to the reset input of a one-minute timer 120. The output of timer 120 is connected to the first terminal of relay winding 104.

The temperature of the working suspension is measured by a sensor 122 which produces an electrical output graduated, for example, in degrees Fahrenheit. The output of temperature sensor 122 is applied to the negative input of a unity gain differential amplifier 128 and to the positive input of a unity gain differential amplifier 130. A source of fixed voltage 124 graduated to represent ambient or room temperature of 70ºF is applied to the positive input of differential amplifier 128. A source of fixed voltage 126 graduated to represent temperature of 100ºF is applied to the negative input of differential amplifier 130. The output of differential amplifier 128 is applied to the negative input of differential amplifier 85. The output of differential amplifier 130 is applied via an amplifier 132 to a trigger circuit 134, the output of which is connected to the first terminal of relay winding 104.

In operation of our invention, the "on" switch 94 is momentarily closed, energizing relay winding 98 through resistor 96 and completing the circuit through switch 105. Relay switch 99 closes and applies voltage from conductor 91 through resistor 102 to winding 98, thereby maintaining it in an energized condition. Closing switch 99 also energizes stirrer motors 18 and 20, energizes primary winding 56, and supplies power to the copier through other connections not shown.

In operation of the toner control system, adjustable aperture 64 causes the amount of light falling on device 68 to equal that which passes through window 62 and falls on device 66 when the working suspension has the desired permeability. In this case, equal voltage drops occur across devices 66 and 68; and the input of amplifier 80 is at ground potential. Potentiometer 67 is adjusted to compensate for slight mismatches of devices 66 and 68. As the permeability of the working developer increases due to consumption of toner, more light falls on device 66, thereby reducing its resistance. An alternating voltage appears at the input of amplifier 80 which is in phase with that at terminal 59. Phase sensitive detector 84 now produces a positive output. When this output exceeds, for example, +0.5 volts, trigger circuit 86 is actuated, causing multivibrator 88 to energize motor 40, for example, in a duty cycle of one second and four seconds. During each one-second interval that motor 44 is energized, it rotates counterclockwise and drives pump 38, thereby supplying toner concentrate from reservoir 14 to tank 10. The four-second interval between successive energizations of motor 40 allows agitator 19 to disperse the toner concentrate in the working suspension. As the permeability of the working suspension decreases due to the increase in the amount of toner, the output of detector 84 decreases; and, for example, at zero volts, trigger circuit 86 is turned "off," thereby turning off multivibrator 88 and motor 40.

The charge director in the working suspension is consumed not only by transfer of carrier liquid to a copy sheet, but also by loss of toner due to transfer of the same to a copy sheet or due to sludge deposition thereof in tank 10. Electrodes 70 and 71 may be formed as parallel plates or as concentric cylinders having diameters of 0.55 inches and 0.45 inches, respectively, and lengths of about 2.5 inches. The spacing between the cylinders may accordingly be about 0.05 inches. The area between the spaced electrodes 70 and 71 is about 3.9 square inches. The working suspension may have optimum properties at a volume conductivity of, for example, 50 x 10¹² Siemens (50 picoohms) per centimeter. This produces a resistance of about 100 megohms between the electrodes 70 and 71. The input of amplifier 81 is at ground potential with the wiper of potentiometer 83 substantially at its midpoint producing -5 volts AC. Potentiometer 73 acts as a variable potential source with a maximum internal resistance of 50 kilohms when at its midpoint, which is one thousandth of the 50 megaohm resistance of fixed resistor 74.

The conductance between the parallel plates or concentric cylinders 70 and 71 is proportional to the area and inversely proportional to the distance between them. The same relationship also holds for the capacitance between the plates or cylinders 70 and 71. Isopar-G has a dielectric constant of 2.0; and the capacitance between the plates 70 and 71 is approximately 35 picofarads. At a frequency of 60 hertz, the capacitive reactance between the plates 70 and 71 is 75 megohms. Capacitor 72, nominally 35 picofarads, is adjusted to equal the capacitance of the plates 70 and 71 so that the input of amplifier 81 can have a zero quadrature component. The equivalent capacitance of the plates 70 and 71 and of the capacitor 72 is 70 picofarads, which means a capacitive reactance of 37.5 megohms at a frequency of 60 hertz. This is shunted by the equivalent resistance of 33.3 megohms of the resistor 74 and the plates 70 to 71.

As the conductivity of the working suspension in tank 10 decreases due to consumption of charge director, the resistance between plates 70 and 71 increases. In the absence of capacitive effects, this would produce an alternating voltage at the input of amplifier 81 which is in phase with the -10 volt alternating current potential at terminal 59. Due to the capacitive action of plates 70 to 71 and neutralizing capacitor 72, the voltage at the input of amplifier 81 lags that at terminal 59 by arctangent (33.3/37.5) = tan-1.89 = 41.6º. Capacitor 77 has a value approximately one thousand times the 70 picofarad equivalent capacitance of plates 70 to 71 and capacitor 72; and resistor 76 has a nominal resistance equal to one thousandth of the 33.3 megohm equivalent resistance of plates 70 through 71 and resistor 74. Resistor 76 is adjusted so that the reference voltage on conductor 78 lags that at terminal 59 by 41.6º. Slight errors in the adjustment of capacitor 72 will produce only voltage components at the input of amplifier 81 which are 90º out of phase with the reference signal on conductor 78 produced by detector 83. Accordingly, detector 83 will produce no voltage output. However, by increasing the resistance between plates 70 and 71 due to the decrease in conductivity of the working suspension, a voltage component is produced at the input of amplifier 81 which is in phase with the reference signal applied to detector 83 on conductor 78. Phase sensitive detector 83 will now produce a positive output. We prefer AC conductance measurements despite capacitive effects to prevent any net buildup of toner on electrodes 70 and 71 that may occur if DC potentials were applied to it.

The working suspension has a positive temperature coefficient of bulk conductivity which may be, for example, +0.5 103w12 Siemens (+0.5 picoohms) per centimeter per degree Fahrenheit. Thus, at a temperature of 100ºF, the same working suspension with optimum properties may have an increased bulk conductivity of [50 + 0.5 (100-70)] 10⁻¹² = 65 10⁻¹² Siemens (65 picoohms) per centimeter. If the temperature of the working suspension rises above 70ºF, the output of differential amplifier 128 becomes negative. The increased volume conductivity of the working suspension produces a negative output of detector 83. The volts/ºF slope of sensor 122 and the gain of amplifier 82 should be such that the negative outputs of both amplifier 128 and detector 83 are substantially equal so that no output is produced at differential amplifier 85 as long as the composition of the working suspension does not change, regardless of changes in its temperature. The conductivity measurement is thus modified by correcting for changes in conductivity caused by changes in developer temperature from 70ºF. As the amount of charge director in the composition of the working developer gradually decreases, the output of amplifier 85 gradually increases.

When the output of amplifier 85 exceeds, say, +0.5 volts, trigger circuit 87 is activated, causing multivibrator 90 to energize motor 44 in a duty cycle of, say, a quarter of a second "on" and five seconds "off." Pump 42 may have one-fifth the volume or displacement of pump 38. The amount of charge director concentrate to be added is extremely small. The five second "off" interval allows the agitator 19 to thoroughly mix the added charge leveler with the working suspension.

During each quarter-second interval that motor 44 is energized, it drives pump 42 counterclockwise and supplies charge regulator to tank 10 from third reservoir 16. As the conductivity of the working developer increases, the output of amplifier 85 decreases; and at, say, zero volts, trigger circuit 87 is switched "off" and turns off multivibrator 90 and motor 44.

The following examples of working developer and toner concentrate are for illustrative purposes only and not for limitation. A 1% working developer suspension may comprise 990 grams of Isopar-G and 10 grams of toner solids including pigment and binder. Optimum properties are a conductivity of 50 x 10-12 Siemens (50 pico-ohms) per centimeter at 70ºF, which may require 238 milligrams of a particular charge director. The loss of each gram of toner solids, whether by transfer to a copy sheet or by sludge deposition in tank 10, may remove 4 milligrams of charge director.

Each gram of carrier liquid transferred to a copy sheet can remove 0.2 milligrams of charge director. The 10 grams of toner solids require 4 x 10 = 40 milligrams of charge director; the Isopar carrier requires 990 x 0.2 = 198 milligrams of charge director; and the total amount of charge director is 40 + 198 = 238 milligrams. A 10% toner concentrate can contain 00 grams of toner solids including pigment and binder and 900 grams of Isopar-G. The toner concentrate preferably further contains 4 milligrams of charge director associated with each gram of toner solids, or 4 x 100 = 400 milligrams of charge director to prevent sludge deposition. However, the toner concentrate preferably contains little or no additional charge director, which is part of the 900 grams of Isopar. The toner concentrate is thus deficient in 900 x 0.2 = 180 milligrams of charge director to ensure that the system maintains regulation. The carrier liquid in the first container 12 is also deficient in charge director, since there is preferably little or no charge director in it. Any further charge director needs are satisfied with the charge director concentrate in the third container 16.

To turn the copier off, the spring-loaded, manually operated "off" switch 108 is momentarily depressed, thereby supplying a direct current to coil 104 through resistor 110 and rectifier 112. Energization of coil 104 opens switch 105, which breaks the circuit for coil 98. Switch 99 thus opens and turns off power to the copier. The copier also automatically turns itself off if no copies are made for a period of one minute. As long as copies are made more than once per minute, the copy sensor 118 resets the one-minute timer 120 before producing an output. However, if no copy is made for a period exceeding one minute, the copy sensor 118 does not reset the timer 120 until its timing has expired. When the one minute period of timer 120 expires, an output signal is produced which energizes winding 104, opens switch 105 and breaks the circuit for winding 98. Switch 99 now opens and turns off the power to the copier.

When the conductivity monitoring system is operating normally, the output of amplifier 85 gradually increases from zero volts to approximately 0.5 volts, whereupon charge converter concentrate is added until the output of amplifier 85 again drops to zero volts. If the third container 16 no longer contains charge converter concentrate, or if there is a fault in the trigger circuit 87, the multivibrator 90, the motor 44 or pump 42, the output of amplifier 85 gradually rises above 0.5 volts. Diode 115 may be silicon and requires approximately 0.5 volts of forward bias to conduct. The input of trigger circuit 116 now begins to rise from ground potential. When the output of amplifier 85 exceeds +1.0 volts, the input of trigger circuit 116 exceeds +0.5 volts, causing it to operate and energize winding 104. Relay switch 105 is opened, breaking the circuit for winding 98. This opens switch 99 and turns off the power to the copier. Although the copier can be temporarily turned "on" by pressing switch 94, it is immediately turned "off" by amplifier 85 through switch 114, diode 115, trigger circuit 116 and winding 104, which opens switch 105. It is desirable that the copier be unable to operate with significantly less charge director in the working developer than is required for optimum performance of the system. Significantly reduced amounts of charge director would cause more rapid sludge deposition of toner in tank 10, which would not only result in loss of toner material but also in more frequent maintenance.

In general, the copier can be restored to operation by adding a new supply of charge director concentrate to tank 16. However, the output of amplifier 85 still exceeds +1.0 volts. To prevent this output of amplifier 85 from turning the copier "off," switch 114 is opened. The input of trigger circuit 116 drops to ground potential, turning trigger 116 "off," and de-energizing relay winding 104. Motor 44 now causes charge director concentrate to be pumped from tank 16 into tank 10. When the output of amplifier 85 drops below +1.0 volts, switch 114 can be closed. Trigger circuit 116 is not turned "on" because its input is less than +0.5 volts. Charge director concentrate continues to be pumped until the output of amplifier 85 falls to ground potential and trigger circuit 87 is switched "off".

The copier normally operates at developer temperatures below 100ºF, where the sludge deposition rate is acceptably low. For example, if a cooling fan fails, the developer temperature rises above 100ºF. The output of differential amplifier 130 goes positive and actuates trigger circuit 134 through amplifier 132. This energizes winding 104, turns the copier "off" and prevents any further increase in developer temperature or increase in sludge deposition rate.

It can be seen that we have accomplished the objects of our invention. We have provided a system for independently controlling the amount of carrier liquid, the amount of toner solids and the amount of charge director in a working liquid developer. The level or volume of the carrier liquid is controlled by the neck 24 of container 12. The amount of toner concentrate is determined by a symmetrical transmittance measuring system wherein equal amounts of light are incident on matched photosensitive devices. The amount of charge director concentrate is determined by an AC conductivity measurement wherein the inherent capacitance between the conductivity measuring electrodes is compensated by a symmetrical circuit utilizing a phase sensitive detector. To prevent both sludge deposition of the toner concentrate and inability to control the charge director control system, the toner concentrate contains a total amount of charge director that does not significantly exceed that associated with the toner solids and contains little or no charge director associated with the carrier liquid component. Our system does not exhibit any of the so-called "fatigue" phenomena of prior art systems that use the toner concentrate to add superfluous charge directors. charge director. In such systems, the conductivity of the working developer gradually increases, causing an excessive rate of discharge of the photoconductive surface and the latent image thereon. To prevent excessive sludge deposition of the working suspension when the charge director concentrate is exhausted or the control system fails, the copier is automatically shut down and prevented from further operation. The copier is also shut down when the temperature of the working suspension rises above a point where the sludge deposition rate is still acceptably low. The conductivity measurement is modified by correcting for changes in the developer conductivity caused by changes in its temperature.

It is to be understood that certain features and sub-combinations are useful and may be used without reference to other features or sub-combinations. This is intended and encompassed by the scope of our claims. It is further apparent that various changes in detail may be made within the scope of our claims. It is therefore to be understood that our invention is not limited to the specific details shown and described.

In the above description, the units of temperature are given in degrees Fahrenheit and the units of length in inches. Note that x degrees Fahrenheit is equal to (x-32)5/9 degrees Celsius and that an inch is equal to 2.54 centimeters. Accordingly, the values given in the text have the following equivalents:

Value in text Metric equivalent

70ºF 21.1 degrees Celsius

100ºF 37.8 degrees Celsius

0.55 inches 1.40 cm

0.45 inches 1.14 cm

2.50 inches 6.35 cm

0.05 inches 0.13 cm

3.9 square inches 25.16 cm²

Claims (20)

1. A liquid developer control system comprising with: i) a tank (10) containing liquid developer which comprises carrier liquid, toner and charge director as components, (ii) a first supply (14) of toner, iii) a first device (60, 62, 64, 66, 68) for measuring the optical transmittance of the liquid developer, iv) a device (40) which responds to the first measuring device (60, 62, 64, 66, 68) and supplies toner from the first supply (14) to the tank (10) and v) a second device (70, 71) for measuring the conductivity of the liquid developer marked by: (vi) a second supply (16) of charge regulators, vii) means (83, 44) responsive to the second measuring means (70, 71) for supplying charge leveler to the tank (10) from the second supply (16) and viii) a third supply (12) of carrier liquid, which supplies carrier liquid to the tank (10). 2. The system of claim 1, wherein the first means includes a pair of matched photosensitive devices (66, 68) that receive substantially equal amounts of light from a common light source (60) when the developer liquid has the desired transmissivity, one device (66) being responsive to source light transmitted through the liquid developer. 3. The system of claim 1, further comprising means (19) for moving the liquid developer. 4. The system of claim 1, wherein the second supply (16) contains a charge director concentrate comprising charge director and carrier liquid, the concentration of charge director in the charge director concentrate being significantly higher than the concentration of charge director in the liquid developer. 5. The system of claim 1, wherein the first supply (14) contains a toner concentrate comprising toner dispersed in carrier liquid, the concentration of toner in the toner concentrate being much higher than the concentration of toner in the liquid developer. 6. The system of claim 5, wherein the liquid developer contains a first amount of charge director associated with the toner and a second amount of charge director associated with the carrier liquid, and wherein the toner concentrate contains a total amount of charge director that does not significantly exceed the amount of charge director associated with the toner. 7. The system of claim 5, further comprising means (21) for moving the toner concentrate. 8. Liquid developer control system provided with : i) a tank (10) containing liquid developer which comprises carrier liquid, toner and charge director as components, ii) a device (70, 71) for measuring the conductivity of the liquid developer, characterized by: means (83, 85, 44, 42) responsive to the measuring means for controlling the supply of the charge director component to the liquid developer independently of the supply of the toner component to the liquid developer. 9. The system of claim 8, wherein the charge director component is soluble in the carrier liquid component. 10. A system according to claim 8, wherein the means for measuring the conductivity of the liquid developer comprises a pair of spaced electrodes (70, 71), the space between them being filled with liquid developer, a variable AC voltage source (56, 58), means for connecting one terminal (57) of the source to one electrode (70), a resistor (74), means including the resistor for connecting the other electrode (71) to the other terminal (59) of the source, and wherein the means for controlling the supply of the charge director component responds to the voltage at the other electrode. 11. The system of claim 10, wherein the resistance is fixed. 12. A system according to claim 8, wherein the means for measuring the conductivity of the liquid developer comprises a pair of spaced electrodes (70, 71) with the space between them filled with liquid developer, the electrodes having a predetermined conductance and a predetermined capacitance therebetween, an alternating voltage source (56, 58), means for connecting a terminal (57) of the source to one electrode (70), a capacitor (72) having a value approximately equal to the predetermined capacitance, means including the capacitor for connecting the other electrode (71) to the other terminal (59) of the source, and wherein the means for controlling the supply of the charge director component is responsive to the voltage at the other electrode. 13. The system of claim 12, wherein the capacitor is adjustable. 14. A system according to claim 8, wherein the means for measuring the conductivity of the liquid developer comprises a pair of spaced electrodes (70, 71), the space between them being filled with liquid developer, a first AC voltage source (56, 58), means for connecting one terminal (57) of the source to one electrode (70), a capacitor (72), means including the capacitor for connecting the other electrode (71) to the other terminal (59) of the first source, a variable discharge source (73), a resistor (74), means including the resistor for connecting the other electrode to one terminal of the variable source, means for connecting the other terminal of the variable source to the other terminal of the first source, and wherein the means for controlling the supply of the charge director component is responsive to the voltage at the other electrode. 15. The system of claim 14, wherein the resistance is fixed. 16. The system of claim 14, wherein the capacitor is adjustable. 17. A system according to claim 8, wherein the means for measuring the conductivity of the liquid developer comprises a pair of spaced electrodes (70, 71) with the space between them filled with liquid developer, an AC voltage source (56, 58), means connecting the source to one electrode (70), a phase sensitive detector (83) having a signal input and a reference input, means connecting the other electrode (71) to the signal input, means (76, 77) for generating a voltage having a predetermined phase shift with respect to the source other than 0° or 180°, means (78) for applying the voltage to the reference input, the means for controlling the supply of the charge director component being responsive to the phase sensitive detector. 18. The system of claim 8, wherein the means for measuring the conductivity of the liquid developer generates a first signal when the conductivity is slightly below a desired value, and a second signal when the conductivity is significantly below the value, and wherein the response means increases the charge converter component in response to the first signal and switches the device off in response to the second signal. 19. A liquid developer control system according to claim 8, which is present in an electrostatic copier, which has means (122, 134) for measuring the temperature of the liquid developer, means (130) responsive to the temperature measuring means for generating a signal when the temperature exceeds a predetermined value (at 126), and means (108) responsive to the signal for turning the copier off. 20. The system of claim 8, further comprising means (122, 134) for making a temperature measurement of the liquid developer, and means (130) responsive to the temperature measurement for modifying the conductivity measurement.