DE2141870A1 - Electrophotographic copier - Google Patents

Description

description

to the patent application

ADBESSOGRAPH-MULTIGEAPH COEPORATION, Mount Prospect / Ill., USA

concerning

"Electrophotographic copier"

The invention relates to an electrophotographic copier in which an image-wise charged electrophotographic Recording material is developed in a developing device by means of a developer mixture and in which to achieve best development results the ratio of toner-'ZU Carrier particles of a developer mixture used is monitored and controlled, and relates in particular to a device of this type in which the electrical properties of the developer mixture can be monitored so that the ratio Toner to carrier particles is kept essentially constant.

For monitoring and controlling the ratio of toner to carrier particles in a dry developer mix for electrostatic and electrophotographic copiers, respectively, are various Facilities known. For some the were. * Facilities changes in the resistivity of the developer mixture monitors when the toner becomes depleted after some operating time, while other devices of this type have optical measuring and scanning devices for measuring the reflectance of light from the toner

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can be used, which is applied to a test piece to to determine the toner-to-carrier ratio and to regulate it accordingly. Highly other devices of this type take advantage of the capacity changes in a condenser device which is introduced into the developer mixture.

Although the known devices mentioned are largely satisfactory work to keep the toner to carrier ratio in Keeping a dry developer mixture essentially constant is shown by the use of these devices various disadvantages. For example, the devices mentioned are relatively complex in structure and require frequent inspection, to work satisfactorily for a long time. Some of the previously known monitoring devices work on best when mixing developers whose ratio of toner to Carrier particles is within a limited range.

The invention is based on the object of creating a monitoring and control unit for electrophotographic copiers, with which, with a simple structure, the ratio of toner to carrier particles is mixed in a dry developer can be kept at an optimum value for achieving the best copy quality over long periods of operation.

Brief summary, the invention consists in a preferred embodiment in a device for monitoring and controlling the ratio of toner to carrier particles in a dry developer mixture for electrophotographic copying devices in that an inductive measuring sensor with a coil and iron core is used. The coil is arranged in the housing of the developer device of the electrophotographic copier and is in contact with the dry developer mixture, which contains toner and magnetizable carrier particles. Dei ^v inductive reactance of the coil is a function of the proportion of magnetizable particles in relation to the proportion of toner particles in the mixture. As the toner becomes depleted, the inductance of the coil changes. The frequency of an oscillator coupled to the coil changes with changes in the coil

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inductance. The frequency change provides an additional Circuits a corresponding output signal, which in turn actuates a toner metering unit which adds toner to the mixture in order to restore the toner to carrier ratio to a predetermined one To adjust the value.

The invention and advantageous details are explained in more detail below using an exemplary embodiment with reference to the drawing explained. It shows:

Fig. 1 is the circuit diagram of a preferred embodiment of the Circuit of the monitoring and control device according to the invention, and .

Fig. 2 is a side sectional view of a magnetic brush developing device; in which the inductive monitoring and control device according to the invention is used.

In Fig. 1, reference numeral 10 denotes the control circuit and 12 denotes the inductive feeler or measuring sensor device which is preferred Embodiment of a monitoring device according to the invention and controlling the ratio of toner to carrier particles in a dry electrophotographic developer mix Called copiers.

The control circuit 10 has a plurality of stages, each bordered by dashed lines, which are connected to one another in a T and em circuit. A first oscillator stage 14 with a variable frequency is connected to an amplifier and discriminator stage 16, which in turn is connected to a buffer stage 18. The outputs 20 and 22 of the buffer 18 are connected to circuit networks 24 and 26 which are coupled to one another and which have a driver unit 28 for a toner refreshment function? Operate the refill unit or a display device 30 which indicates when the toner-to-carrier ratio is outside the desired values. In order to stabilize the control circuit and for compensating for changes in voltage of the input span -nung ¹ is a voltage regulator circuit 32 to the buffer

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, .level 18 connected ..

First, the individual stages of the control circuit 10 are explained in detail:

The voltage and power supply of the control circuit takes place via the input terminal 34, which is connected to the positive pole of a 26 volt DC power source, not shown, is connected. A Connection point 36 is at ground potential.

The variable oscillator stage 14 consists essentially of a conventional Collpitt oscillator with a transistor 38, the is connected as an emitter follower. The voltage supply of the transistor 38 takes place via resistors 41, 4-3, their ■ connection point is connected to the base 45 of the transistor 38. The collector 40 is connected to an oscillator circuit, which has a tunable inductor 42 and capacitors 44,46. The capacitors are via a line 48 with a End of an inductive measuring or touch probe 12 connected, while the tunable inductance 42 via a line 50 with the other terminal of the sensor 12 is connected. The sensor has at least one measuring winding 13 with preferably an iron core. A preferred embodiment of this measuring coil is explained in more detail below with reference to FIG.

The parts of the oscillator circuit which determine the fundamental frequency of the oscillator 14 are the capacitors 44, 46 and the tunable Inductance 42. The inductance 42 can be tuned in such a way that an adaptation of the oscillator circuit 14 to the Sensor coil 13 can be made, which is then used in the area of a developer mixture that has a certain ratio from toner to magnetizable particles such as iron particles.

A voltage divider network 52 contains resistors i, 4, 6 and is connected via a capacitor 62 to the base 64 of a transistor 60 which, in an emitter-base circuit, serves as an amplifier for the amplifier and discriminator stage 16 of the control circuit according to the invention. The base 64 is above a first

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Resistor 68 to positive lead 70 and across a second Resistor 72 is applied to ground line 74 ·. The emitter 76 is via the parallel connection of a resistor 78 and of a capacitor 80 on the ground line 74 ·· The collector of transistor 60 is connected to a tuned network 84 comprising a capacitor 86 and an inductor 88, which serves as the primary winding for a transformer 90. The network is usually tuned to a normal operating frequency of around 15 kHz.

The primary winding 88 is inductively loosely coupled to the secondary winding 92, 94- of the discriminator part of stage 16. Capacitors 96, 98 form in parallel with the associated secondary winding parts oscillator circuits 100, 102, which are tuned to frequencies of about 16 kHz or 14 kHz.

The series arrangements of diode and capacitor 104, 106 and 108, 110 serve to rectify the output signals occurring via the assigned capacitors 96 and 98, respectively. Parallel resistors 105 are connected to the oscillator circuits 100 and 102, respectively and 107.

Normally the output signals are via the respective capacitors 106, 110 before inserting the sensor winding 13 in the toner-carrier mixture the same, but point opposite te polarity and cancel each other out. That is, the output signal of the discriminator circuit is zero in this case.

If the coil 13 is placed in the area of the toner-carrier mixture, the frequency of the oscillator circuit drops because of the magnetic properties of the carrier particles in the mixture. A decrease in the frequency causes the coupling between the pri-; The secondary winding 88 and the secondary windings 92, 94 with the 14 kHz secondary oscillator circuit become harder because the oscillator frequency drops from the originally set value at 15 kHz, while a looser coupling with the other secondary winding of the other oscillator circuit is established . Since the positive charge of the capacitor 106 is greater than the opposite nega-

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tive charge of the capacitor 110, the output of the Discriminator positive with a signal amplitude that depends on the ratio of the frequency of the variable oscillator stage to the 14 kHz frequency of the oscillator circuit 100.

A thermistor 112, the parallel to the capacitor 110 lies. The thermistor compensates for temperature fluctuations from about 4.4 to about 71 ° C

With the outputs 114, 116 of the amplifier discriminator stage a field effect transistor 118 is connected. As protection of the field effect transistor Against the input-side overvoltage, a Zener diode 120 is connected in series with a V / resistor 122 across the output terminals 114, 116 of the amplifier discriminator stage.

A resistor-capacitor combination 124, 126, which is connected to the gate electrode 128 of the field effect transistor 118, serves as a time delay network 130 to delay the output signal voltage impressed on transistor 118 in order to prevent this transistor from sudden voltage changes due to frequency changes caused by the coil 1 $ caused, is exposed. In this way, transistor 118 will only operate with relatively slow voltage changes applied.

The field effect transistor 118 or Darlington transistor, as it is sometimes called, is connected as an emitter follower, whose drain electrode 132 is connected to the positive direct current line 70, while the source electrode is connected to a. Pair of series-connected resistors 136, 138 is connected, through which the output signals for the circuit network 24, 26, which will be explained further below, is delivered to lines 20 and 22, respectively.

The field effect transistor 118, which is connected as an emitter follower, does not provide any further amplification of the output signal of the Amplifier discriminator stage 16, but rather serves as

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Impedance converter to get a low output impedance at relative high signal power to operate the circuit network 24, 26 to receive.

As already mentioned, voltage regulator circuit 32 is the same any voltage changes in the DC power supply. This voltage regulator $ 2 contains a resistor 140, which is connected to the positive terminal 34 and in Series for the parallel connection of a Zener diode 142 and a capacitor 144 is located. The regulating circuit holds the voltage at an equivalent of about 22 volts.

The circuit network 24 to be described now has a switch arrangement using conventional potted circuit technology or solid-state technology with a first and a second transistor 146, 148. The voltage at output 20 is the Base 150 of transistor 146 pushed on. Between the base and the output 20 of the buffer stage 18 of the control circuit is a resistor 152. The base 150 is also with a capacitor 157 connected, which in turn is connected to ground 36. Of the Emitter 147 of transistor 146 is connected to ground 36 via a Zener diode. Collector 155 is connected to a pair for current limiting Serving resistors 156, 158 and connected to the base 160 of the transistor 148. The zener diode 154 sets and stabilized, .the operating voltage for the transistor 146. The ^ The voltage at the base of transistor 146 must be the Zener breakdown voltage of diode 154 plus the voltage drop across the Exceed the emitter-base path of the transistor 146 before this transistor becomes conductive. In practice, the breakdown voltage is of diode 154 about 9 * 1 volts and the voltage drop about 0.5 volts across the base-emitter path.

The emitter of the transistor 1 ^ -8 is connected to a positive potential leading line 165 connected, which in turn is connected to the positive terminal 34 of the DC power supply. Of the Collector 164 of transistor 148 is connected to an electrical coupling 166 of drive 28 of the toner refill device

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connected to a screw in a toner refill (Fig. 2) drives the toner in the developer unit, the the developer mix contains to refresh. Between the base 150 of transistor 146 and collector 164 of the transistor A resistor 169 is connected to 148. A Zener diode 168 is connected in parallel to the coupling 166 to prevent damage to the transistor 148 to prevent the actuation of clutch 166 being interrupted, when enough toner has been replenished in the developer mix. The one at resistor 158, i.e. tapped at output 22 The output voltage is sent to the switch network 26 via the supply line 22 supplied. The switch network 26 also includes a pair of transistors 170 »172. The emitter 174 of the transistor 170 is connected to the emitter 147 of the Transistor 146 of network 24 and connected to diode 154, while the base 176 of this transistor has a capacitor 178 is connected to the line 180, which leads to the other side of the diode 154. The collector 182 of the transit gate 170 is used to limit the current via a pair in Series of connected resistors 184, 186 connected to the line 165 carrying positive potential.

The base 188 of the transistor 172 is connected to the connection point of the resistors 186, 184. The emitter 190 of the The last-mentioned transistor is connected to the line 165 carrying the positive potential, while the collector 192 is connected to a resistor 194 of a pair of resistors 194, 196 to the base 176 of transistor 17O is connected. The resistance 196 is on the other hand connected to the output 22 of the buffer 18.

A lack of toner indicator lamp 198 is over . a line 200 is connected to the collector 192 of the transistor 172. A circuit arrangement delivering an error signal 30 consists of the series connection of two resistors 202, 204 and is also connected to the collector 192 in order to send a signal via line 206 to interrupt operation of the copier to produce, in which the device according to the invention is used. One between the switch networks 24, 26 across

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the lines 165 * 175 parallel resistor 208 supplies a common reference voltage for both networks. the Zener diode 154 is used for "both networks and the transistor 170 only works when the voltage at input 22 of base 176 of transistor 170, the breakdown voltage the zener diode 154 plus the voltage drop across the emitter 174 exceeds. These operations are discussed in more detail Details in connection with the explanation of the mode of operation of the device according to the invention, which the control circuit 10 contains, explains.

Fig. 2 shows in a sectional view a developer unit 210, which the subject of a February 6, 1970 under Ser. Ko. 9J16 pending U.S. patent application and intended for use in high speed electrographic copiers is.

The developer unit 210 comprises a hollow cylinder or a Roller 212 carried by a fixed shaft 214 and supported by bearings 216.

A device 218 is connected to the shaft 214, which is used to generate a magnetic flux and a series of permanent magnets, such as the magnet 220, which are arranged in the • cylinder 212 in order to be on the outer shell of the cylinder to arrange the dry developer mixture magnetically in an appropriate distribution, the toner and magnetizable Contains iron carrier particles, and for developing the recording material under a magnetic brush device 222 runs through it.

The hollow cylinder 212 is mounted in a housing 224 which also contains two pairs of feed rollers, of which only a pair 226 is shown and is used to convey the recording material in the direction of a path indicated by the arrow 228 behind the cylinder 212.

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The developer mixture with a "certain mixing ratio of toner and iron carrier particles is first placed in a trough (not shown) under the cylinder 212 to be used for development of the recording material guided along path 228 to serve. During the development of the recording material, the proportion of the toner particles in the mixture is depleted, so that the ratio of toner to iron particles changes and toner must be added to keep this ratio essentially constant to keep. To refresh the developer mix with Toner, the developer unit has a funnel-like container 230 filled with toner. For thorough mixing of the toner, a part 232 is provided in the container 230, the prevents the particles from caking together while the rotatable auger 234 is positioned below the mixer 232 for additional Dispense toner from container 230 when a signal is present, which indicates that the ratio of the mixture has changed by a certain amount. Should be the specialist and readers of this description need more detailed explanations of the developer unit according to FIG. 2, they should refer to the one already mentioned Patent application are referenced.

Adjacent to the magnetic brush cylinder 212 is the developer unit the direction of passage of the recording material after the development area 228, the sensor coil 13 according to FIG the preferred embodiment of the invention arranged. This preferred embodiment of the probe coil has a centrally arranged cylindrical elongated iron core 236. At the end 237 of the sensor coil 13 near the rotating cylinder 212, a winding 238 is provided. An inner plastic case 240 surrounds the winding and the iron core. At the other end 24-2 of the winding permanent magnets are arranged, the surround the iron core 236. Between the permanent magnets 244 and the winding housing 240 is a dielectric spacer 246 introduced. Additional insulating spacers 248, 250 made of plastic surround the winding and the iron core at the end 237 · An outer housing 252 made of plastic surrounds the magnets 244. The insulating plastic is used for shielding the sensor winding 13 against external stray fields. One

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thin layer 254 of the under the trade name "Mylar" known plastic (terephthalic acid-ethylene glycol-polyester) is between the measuring coil 13 and the "brush" of the developer unit introduced in order to prevent an accumulation of toner particles in the area of the winding.

When the device is in use, the magnets 244 attract the developer mixture remaining on the cylinder surface after it has passed the development area, i.e. towards the end 237 of the winding so that the mixture can be checked. The Gaussian field strength or the magnetic Induction of the magnets is sufficient to attract the developer mixture, but is not strong enough to attract the developer mixture to pull to the end 237 of the winding. This gives an indication of the ratio of toner to carrier particles win in a mixture.

The coil arrangement with an iron core can preferably be used as a measuring device because of the iron core, there is greater sensitivity to changes in the inductance of the coil can be achieved due to the external influence of the mixture. An air core coil does not provide the sensitivity which is sufficient to be able to determine the iron to toner ratio in a dry developer mixture.

Although the measuring coil 13 in the illustrated embodiment preferably arranged in a straight-through direction after the developer zone installation in another area can lead to equally good results. For developer units, at which no magnetic brushes, as in the embodiment according to FIG. 2, are used, for example in cascade developers, the measuring coil is normally arranged where it is convenient with the developer mixture used in the developer unit can be brought into contact.

In the following, the mode of operation of the Facility explained in the interaction of the individual parts. As already mentioned, after the sensor 12 (Widäung 13)

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near the dry mixture of toner and iron particles is arranged in a certain ratio, a positive voltage signal at the outputs 20 and 22 of the buffer stage generated. However, these output voltages are normally too low to put the transistors 146, 170 in the conductive state to control

If recording material runs through the developer unit for development, in this way, toner is applied and withdrawn from the mixture, so that the ratio of toner to iron particles changes changes in the mixture.

A change in the ratio of toner to iron particles results in a greater proportion of iron per toner particle in the mixture remains, whereby the inductance of the coil 13 changes, which in turn changes the frequency of the variable Frequency oscillator 14 causes. This frequency change is amplified and causes the frequency to drop Oscillator frequency of the first oscillator circuit 84. This increases the inductive coupling of the secondary winding, see above that larger output signals occur at 20, 22. The output voltage however, at 20 is about 2 volts higher than the voltage at 22.

'Reaches the voltage at point 20, that of the base' of the transistor 146 of the switch network 24, a certain value, i.e. the value of the Zener breakdown voltage of the Diode 154 (9.1 volts) plus the voltage drop of about 0.5 Volts across the base-emitter path 147 of the transistor, this transistor 146 becomes conductive, i.e. switched on. So that will transistor 148 is also conductive. This transistor 148 in turn switches the electrical clutch 166.

W: xd in the developer unit shown in FIG Clutch 166 is actuated, the screw 234 begins to rotate and conveys toner from the container 230 in the area of the rotating Cylinder 212, so that the predetermined ratio of toner to iron particles in the mixture is readjusted again.

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After sufficient refreshment of the toner material in the mixture changes the inductance of the measuring coil 13 increases so far that the output voltage at point 20 is below that for actuating the transistor 146 required voltage of 9.6 volts drops so that the . Operation of the clutch 166 is interrupted again.

For the pail that there is no more toner in the dispensing container 230 is, i.e. that no more toner is added to the mixture,

the worm 234- via the coupling 166 continues to be rotated. After a short time, however, the inductance of the measuring coil 13 has changed to such an extent that that which can be tapped off at point 22 Voltage which, as already mentioned, is about 2 volts below the voltage at point 22, the specified "- ™

Voltage value, i.e. 9 »6 volts and the transistor 170 of the switch network 26 becomes conductive, so that the transistor 172 also conducts.

When the transistor 172 is switched on, the lamp 198 lights up and shows the operator of the copier that the toner dispenser is in the container There is insufficient or no toner. In addition, there is then a signal on line 206 which is used for Interruption of operation of the copier itself can be used until the container 230 is refilled.

Toner is replenished in the tank 230, the formwork Λ ternetzwerk 26 is no longer excited and the lamp 198 goes out. This means that the copier can also be put back into operation. The switch network 24, however, remains energized until sufficient toner is again available in the developer unit. Is the given ratio of toner to iron part. . \ chen adjusted again, the switch network is also inactive until a further change in the ratio of toner; is registered to iron particles.

The inductive toner sensor device according to the invention can be used for developer mixtures in which the following: i ratio of toner to carrier particles can change over a wide range, with little or no impact

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or readjustment of the circuit is required. Palis required, can be used to set a greaterx sensitivity the inductance 42 slightly adjusted accordingly.

When using the device according to the invention for monitoring and controlling the ratio of toner to carrier particles copies can be made with an electrographic copier that have a high quality and uniform density with good contrast. The device according to the invention is particularly suitable for the recently used, very fast working electrographic copiers, in which the toner content is rapidly depleted and correspondingly large amounts of toner are required. With the device leaves A rapid replenishment of the toner content can be achieved in order to substantially reduce the ratio of toner to carrier particles in the mixture to keep constant., regardless of how quickly the toner is removed from the mixture.

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Claims (3)

- 15 - 1A-39997 Claims ZS ZZ SZ ZZZS ZS ZSZS, SZSSiZS - SS ZZ ZS ZSiSZ SS SiZiXZl ZS ZSSS ZS ZS SSSS ZZtZS Q. Electrophotographic copier "in which an imagewise charged electrophotographic recording material in a developing device by means of a developer mixture is developed, the carrier and electroscope! see toner particles, which are conductive to achieve the best development results in a "certain proportion and in which devices are provided in the developing device to the developer mixture on the charged recording material to apply by moving the former relative to the latter, d a d u r c h ge k e n_n_z__g_J ^ _c_h_n._e. t, that the developing device is equipped with a sensor (13) is, which has an iron core ("^ 36) and a coil (238), encapsulated in an insulating housing (240) and immersed in the path of the developer mixture has that the measuring sensor (13) an inductive signal as a function of the toner / iron ratio generated that one with the sensor (13) connected Control circuit (10) for measuring reactance or inductance changes as a function of the toner / iron ratio and a metering device controllable by the control circuit (230, 234) is provided, which when the reactance value falls below a value indicating that the toner / iron ratio ♦ a predetermined value as a minimum value for best development results has fallen below, releases toner into the developer mixture. 2. Copier according to claim 1, characterized in that the developing device is a Magnetic brush developing facility is. 3. Copier according to claim 1 or 2, characterized characterized in that the control circuit (10) has a Has an oscillator circuit (12) with a certain setpoint frequency corresponding to the optimum toner / iron ratio, which changes its frequency as a function of a change in the inductive reactance value of the sensor (13), and that 2098H / U17- a driver unit in the event of a deviation from the setpoint frequency (28) receives a signal for the toner metering device for the delivery of toner particles to the developer mixture. 4-, copier according to claim 1 or 2, characterized characterized in that the control circuit (10) has a switching device (30) which, as a function of the output signal the oscillator circuit (12) turns on when the oscillator circuit enters an unstable state, i.e. a state outside the specified frequency value, and thus the metering device switches on. 5 · copier according to claim 4, characterized that the switching device (JO) has a first circuit (28) for switching on the metering device and a second circuit (26) for switching off the developing device, of which the second circuit (26) can be activated is when in the alumina dosing device is not sufficient There is more toner available. 2098H / U17 ff Blank page