DE2360389A1 - CONTROL CIRCUIT FOR THE MELTING DEVICE OF A COPYING MACHINE - Google Patents

Description

, .yßitö December 4, 1973

: '· ... : <Jy' P 6924

XEROX CORP. .. "■ -

Xerox Square, Rochester, New York 14605, USA

Control circuit for the "melting device a copier.

The invention relates to a control circuit for the fixing the copy-serving melting device of a copier for maintaining a predetermined power supply to Heating device of the melting device regardless of fluctuations the mains voltage ·.

In electrostatic copying machines, a toner is electrostatically recorded on the copying material Image of the original to be copied is made. To the picture too fix it, it is fused by passing the copy material through a heated furnace, usually used as a furnace referred to as. There is a combination of. V / poor and pressure of the toner melted onto the copy material, so that a permanent copy is created

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With machines of this type, the right temperature is required the melting device. If the temperature of the fuser is too low, the fusing may be incomplete be. This is most commonly seen as smearing or disappearing of the image, especially when you are using of the copy is handling · Is however the. Temperature fusing device too high, there is a risk of the copy material being burned or scorched.

Most melting equipment uses some type of electrical heater, such as a quartz lamp, as a heat source An important factor for the puncture of such a melting device and for the err ei ch ~ of the melting device The maximum operating temperature is the mains voltage. When line voltages differ from the optical voltages for which the heater is built, differ, the temperatures of the melting device can vary so far that it is too poorly fixed Copies is coming.

The invention therefore aims to provide a control device for such Create melting facility. The energy supply to the heating device for the melting device should be controlled by a control circuit the copier can be controlled in such a way that the heater practically always regardless of changes in the mains voltage receives constant energy. This energy supply is intended to be that required for efficient operation of the melting device be restricted. With the help of this control circuit it should be possible to presuppose the melting device for the smallest To interpret mains voltages with the certainty that mains voltages above this minimum will not be impaired the puncture or the melting device itself can be.

According to the invention, this is achieved by a control circuit, which is laid down in the characterizing part of the first claim.

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Further features, details and advantages of the invention result can be seen from the following description of a Äüsführungsbeiapiel based on the drawings.

Fig.1 is a schematic sectional view of an electrostatic Copying machine with the control circuit according to the invention;

FIG. 2 is an enlarged sectional view of the melting device in FIG the copying machine shown in Figure 1; and ,

5 shows a circuit diagram of the control circuit according to the invention for the melting device. "

An example of a copier machine 10 is shown in FIG. the control circuit according to the invention for the Sehmelzeinrichtung. contains.-As with all electrostatic systems, so also of the illustrated xerographic copying machine, a photograph of an original to be reproduced is placed on the sensitized Projected surface of a xerographic plate, to form a latent electrostatic image there. Thereafter the latent image becomes with the help of oppositely charged developer material developed, producing a xerographic powder or toner image which is the latent image on the plate surface is equivalent to. The toner image is then electrostatically transferred to an image receiving surface, where it is passed through a Melting device is fixed so that it adheres permanently to the receiving surface.

In the copying machine 10, an original 12 to be copied placed on a transparent table 14 which is arranged in a stationary manner in a lighting system which is designated as a whole by 15 and is housed at the left end of the machine. The original 12 lying on the Tisen is illuminated, whereby Light rays are generated that correspond to the image areas of the original. The light rays are made with the help of an optical System on the light-sensitive surface of a xerograpit-BChen Projected plate. In the example shown in Fig.1

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a copying machine 10, the xerographic plate has the shape a flexible photoconductive belt 17 attached to a belt guide 18 is supported.

The belt guide 18 of the photoconductive belt 17 comprises three rollers 20, 21 and 22, which with parallel axes approximately to the Points of a triangle are arranged. The upper roller 22 is seated on a shaft 23, which in turn is rotated by a motor and drive, not shown, around the belt 17 in the by the Arrow of Fig.1 indicated direction to move. During this Movement of the belt causes the light pattern reflected from the original 12 on the table onto the photoreceptor surface of the The tape 17 is flashed in an exposure station 25 in order to produce a latent electrostatic image

The continuous movement of the photoconductive belt 17 guides the electrostatic image through a development station 26, in which a developing device, generally designated 28, is arranged. This is where the electrostatic latent image becomes developed with the aid of toner using a multiple magnetic brush system 29 ·

The developed electrostatic image is conveyed from the belt 17 to the transfer station 30, where it is transferred to a receiving surface, normally a sheet of copy paper 31, is transferred. The copy paper sheet is placed between the transfer roller 32 and the belt 17 advanced. So that the developed image exclusively with the help of an electrical bias can be transferred on the transfer roller 32, the copy sheet 31 moves at the same speed as the belt 17 emotional. For this purpose, a sheet transport mechanism is provided, which is designated as a whole by 34. This mechanism promotes Copy sheets 31 from a total-designated 35 Mechanism for handling the paper to transfer station 30.

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After the transfer wlr <3; the <Kapierblatt 31 stripped from the tape 17 and conveyed through a melter 38 in which the toner image is fused onto the copy sheet. After the fixation the finished copy is released into an "output tray 39".

The photoconductive belt 17 consists of a photoconductive selenium layer on a flat base. The selenium layer represents the light-receiving surface of the machine. Further details of the construction of the bandies 17, its relationship to the engine and for the tape guide are in terms of U.S. Patent No. 3,750,623, issued 1.5. 1973, can be seen.

As KLg.2 shows, the seaming unit 38 has a housing 40 in which a lower heated melting roller 41 and an upper pressure roller 42 are housed. The rollers 41 and 42 together form a gap through which the coping sheets 31 run . The rollers 41 and 42 are rotatably supported in a suitable manner and are rotated together by a drive (not shown). The pressure roller 42 consists of a relatively soft material, for example Teflon, neoprene, etc., so that the pressure between the Rollers 41, 42 deform the surface of the pressure roller 42. In this way, there is an enlarged contact sheet between the Kppierblätt ixnä the heated melting roller 41 ″.

In the illustrated embodiment, the melt roller 41 is hollow and formed from a suitable thermally conductive material. A heat source, for example a lamp'44, is arranged in the melting roller. A suitable, temperature-sensitive resistor, ie a thermistor 45, ^ia * on the housing 40 of the melting device in such a way .haltert that it with; the housing is in heat exchange and thus perceives the temperature in the housing 40.

In Pig. 3 a circuit diagram of a control circuit 50 is shown, which serves to de, n input current to the heating lamp 44 of the melting

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device 40 regardless of fluctuations in the line voltage rules. The heating lamp 44 of the Schmelzeinriehtung is with a Power source connected., Which are referred to herein as network connections L1, L2 is shown. There is a matching switch in the connection: - organ, which in the example shown is a silicon-controlled Rectifier 46 is.

A transformer 51 is overlaid with its primary winding 52 the heating lamp 44. The secondary winding 53 of the transformer 51 is connected to the input terminals of a suitable full-wave rectifier 55 connected. A suitable GIk j-ch voltage source for the bias is indicated by the line 53, to which a terminal 56 of the full-wave rectifier 55 is connected. the other output terminal 57 of the two-way rectifier 55 is over a line 64 is connected to the control input 65 of a switching amplifier 66.

A control capacitor 60 is connected in parallel with the terminals 56, 57 of the full-wave rectifier 55 between lines 58 »64 · In line 64 there is a suitable charging resistor 61 for the Capacitor placed between rectifier terminal 57 and capacitor 60. A discharge resistor 62 is connected to the capacitor 60 in parallel.

To control the silicon controlled rectifier 46 is a suitable control element, in the present example the visual amplifier 66, provided. The output terminal of the amplifier 66 is via a line 69 to the control input of the silicon-controlled Rectifier 46 connected. The gate 67 of the amplifier 66 is on a suitable reference DC voltage from the line 58 is set, for which purpose a suitable series resistor 63 is switched on in this line. Line 69 is over a charging resistor 71 a capacitor 70 is connected. Is via the amplifier 66 or between the line 64 and ground A suitable Yiid was available for recruitment at 74 or 75 the voltage level. Between the gate 67 of the amplifier and

BATH ORIGINAL

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A discharge resistor 78 is arranged to ground and a diode 79 connects the capacitor 70 to the resistor 78 · · ■■■ _. ..- ■■ -

When the copier 10 is in operation, the measurement voltages are on the heating lamp 44 of the melting device 40 constantly from the Transformer 51 of the control loop is monitored. The outcome of the Transformer winding 53 is of the .Rectifier. 55 rectified and the resulting DC voltage signal is used to charge the control capacitor 60 through the resistor 61. When the charge on the control capacitor 60 is a predetermined When the height is reached, the voltage signal in the line switches 64 to gate 65 of amplifier 66 the amplifier 66 into the conductive State around. The resulting control signal on the line 69 triggers the silicon-controlled rectifier 46 in the blocking state, whereby the current to the heating lamp 44 of the Melting device is interrupted. With termination of the power supply to the heating lamp 44, the voltage signal generated by the transformer 51 drops and the control capacitor 60 discharges through the resistance 62

In the conducting state of the switching amplifier, s 66 "loads the voltage signal on the line 69 through the resistor 71 the capacitor 70, when the charge on the capacitor 70 reaches the predetermined height, _by;., The resistors 74, 75 determines is the Amplifier 66 switched to the non-conductive state. With the loss of the control signal in the line 69, the silicon-controlled rectifier 46 is switched to the conductive state and the power supply to the heating lamp 44 is restored discharged through resistor 78 to be ready for the next cycle

In the context of the invention are compared to the described and illustrated embodiment changes possible;

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Claims (8)

Claims My control circuit for the melting device of a copier machine, to maintain a predetermined power supply to the heating device of the melting device regardless of fluctuations in the mains voltage, characterized by a first circuit part for monitoring the power supply to the melting device, which in a first switching state allows current zii to pass through the melting device and in a second switching state, the power supply to the melting device interrupts, and by a second circuit part which actuates the first circuit part. 2. Control circuit according to claim 1, characterized in that the first circuit part upon reaching a
predetermined voltage level is switched from the first to the second switching state. . 3. Control circuit according to claim 1 or 2, · characterized in that the second circuit part the first
Circuit part actuated in such a way that after an interruption of the power supply it returns to the first switching state after a predetermined period of time
switches back. 4-. Control circuit according to one of the preceding claims, characterized in that the first circuit part contains a switching element (46) which switches off the melting device from the current source when the current input is switched off
Melting device exceeds a predetermined height. 5. Control circuit according to one of the preceding claims, characterized in that the first circuit part generates signals Contains elements for "monitoring the at the 0.9824 / 102Ό Melting device lying voltage level, which at a predetermined voltage level, a predetermined Generate control signal ", as well as a response to this control signal responsive organ that interrupts the line and terminates the power supply to the melting device, and that a delay element is contained in the second circuit part, according to a predetermined Time span restores the feed line to the melting device. - "" .- "*. 6. Control circuit according to one of the preceding claims, characterized ^ that the second circuit part the includes the following parts: A first capacitor (60), which at a given. Charging the switching element in the second switching state switches over, whereby the power supply to the heater is interrupted, further a switching arrangement for charging of the first capacitor proportional to the an the heating device lying line voltage, a second capacitor (70) which, with a predetermined charge, puts the circuit element in the first switching state transferred, whereby the heating device is supplied with power, and finally an arrangement for charging of the second capacitor (70) to the switching of the Switching element into the second switching state. 7. Control circuit according to claim 6, characterized in that the switching element (46) through a predetermined control signal can be converted into a blocking state in which there is the power supply interrupts to the heating device that also a control member. (66) is provided, which is in a first switching state supplies this control signal and terminates the control signal in a second switching state, and that this control element (66) is operated by a switching arrangement which 409824/1020 Most capacitor (60) contains, and a switching arrangement for charging the first capacitor proportional to the on the heating device lying voltage, wherein such an arrangement is made that with a predetermined charge of the first capacitor, the control member (66) in its first switching state is transferred and thus the switching element (46) in the blocking state, whereby the power supply to Heating device is interrupted, and finally a second condenser, which by switching the control- organs is chargeable to the first switching state, such an arrangement is made that when the second capacitor (70) is charged, the control element (66) is transferred to the second switching state, whereby the switching element (46) is switched to the conductive state and the power supply to the heater is restored. 8. Control circuit according to claim 1, characterized in that responsive devices are provided on the input of the melting device which are responsive to a predetermined power to switch the first circuit part in the second switching state, so that the energy supply to the. Melting device is interrupted; and that the first circuit part can be switched back to its first switching state after a predetermined period of time by the second circuit part, so that the energy supply to the melting device is restored. 409824 / 102Q L e r s e i t e