DE1522727B2 - ELECTROPHOTOGRAPHIC PROCESS AND COPY DEVICE TO MAKE MULTIPLE COPIES - Google Patents

Description

The present invention relates to an electrophotographic process for making a plurality Copies in which a charge image is generated with a toner develops the toner image in one electric field is transferred to an image receiving material and the charge image for each additional copy redeveloped and the toner image in an electric field onto another image receiving material is transmitted. The invention also relates to a copier for carrying out such a copier Procedure.

In a method known from French patent specification 1,379,820 of the abovementioned Art is the charge image on a cylindrical drum that has a photoconductive surface layer has generated. The charge image is then developed using a developer brush, and that which is generated in the process Toner image is deposited on a sheet-shaped image receiving material pressed against the surface of the drum transferred by means of a corona discharge on the side of the image receiving material facing away from the drum is produced. Then the charge image is again applied with a developer brush developed, and the second toner image thereby formed is transferred to another in the same way as the first Transferring image receiving material.

A disadvantage of this known method is that the contrast of the copies from copy to copy decreases.

The invention is accordingly based on the object of an electrophotographic process for making multiple copies, all of which have approximately the same contrast.

This object is achieved according to the invention

solved an electrophotographic method of the type mentioned, which is characterized in that that the transfer of the toner images takes place with increasing field strength from copy to copy.

A copier for performing this method with a device for generating a charge image on an electrophotographic recording material and several alternately successive Development and toner image transfer devices are in accordance with the invention thereby characterized in that each toner image transfer device has two electrically conductive rollers which are connected to voltage sources, which voltages generated by the toner image transfer device to provide toner image transfer device.

According to one embodiment of this copier, at least one of the two rollers is made of conductive material Rubber. This enables a particularly effective transfer of toner images from copy to copy practically constant contrast achieved.

In the following there are exemplary embodiments of the method according to the invention and of copiers for the implementation of the method according to the invention explained in more detail with reference to the drawings, it shows

F i g. 1 is a graphical representation of the various Steps of an electrophotographic process for making multiple copies,

F i g. 2 to 5 are schematic representations of process steps and the devices used for them an embodiment of the method according to the invention,

F i g. 6 is a schematic side view of an automatically and continuously operating copier for carrying out the method according to the invention,

F i g. 7 shows a vertical section through a development station of the one shown in FIG. 6 illustrated copier, and

F i g. Fig. 8 is a side view of another automatic copier for implementation of the method according to the invention.

In the block diagram of FIG. 1 are the various operations that are required to carry out of the method according to the invention are required, illustrated. The charge image can be on the surface a recording material are produced which has a photoconductive zinc oxide layer on a has relatively good conductive layer support, for example made of paper. The first step consists in the uniform charging of the photoconductive layer, for example using a Corona discharge. The second step consists in the imagewise exposure of the photoconductive layer with the template. Instead of this, the charge image can also be applied to an insulating surface, for example on an insulating plastic sheet, by imagewise charging in a manner known per se Generate way.

Regardless of which of these two methods is chosen, many copies can now be made The reason for this charge pattern is given by the following in FIG. 1 produce operations 3 to 7 shown. The first copy is created through the third process of developing the charge image a toner, through the fourth step of the

3 4

Transfer of the unfixed toner image to a sheet- The roller 38 receives compared to the roller 40 with-

shaped image receiving material on which the image is subjected to a voltage by means of a DC voltage source 42,

can be fixed if desired. A second as shown in FIG. 5 is shown. The roller can

Copy can be in a fifth step by 38 either negative or positive compared to the

a new development of the charge image and be in 5 roller 40, depending on whether a toner is used to produce

a sixth step through a renewed delivery of a positive or a toner for production

A negative of the original was used to transfer onto another image receiving material, d. H.,

on which this second copy is in turn fixed depending on whether the loaded or unloaded load

can be. A seventh operation is shown in FIG. 1 as rich were developed.

a repetition of operations five and six io the applied between rollers 38 and 40

for each additional copy required. Voltage can be between 50 volts and more than

In Fig. 2 to 4 is a device illustrative- 1000 volts. If the electroscopic light, with which in manual operation a charge image toner, which is used to develop the negative charge a recording material 10 to be generated image was used is positive, the roller 38 can. This has a relatively good conduct 15 compared to the roller 40 negative to a positive the substrate 12, for example made of paper, from the original to the image receiving material Preserved with a moisture content of about 5 to 6% and positive when to reverse development and a layer 14 of photoconductive zinc oxide combine a negative toner in the negative charge image suitable resinous binders. That was expended. When the image receiving material is 34 Drawing material 10 can preferably be peeled off the form 20 from the recording material 10, remains have a flat plate, but need not necessarily- a part of the toner powder on the underside 36 hang ^ · to be agile. gen and forms the first copy of the template. These

The surface of the photoconductive layer 14 can be copied through, for example, if desired

Evenly negatively charged electrostatically, heating can be fixed.

The, for example, by a known per se 25 A plurality of further copies can be direction 18 for generating a corona discharge. through a renewed development of the charge pattern The corona wires 20 of the device 18 are connected according to FIG. 4 and by transferring this unfixed a negative terminal of a DC voltage source newly developed image to another image receiver for example 6000 volts. A positive clamp of starting material 34 as shown in FIG. 5 generate. The Spandies Voltage source is connected to an electrically conductive 30 voltage between rollers 38 and 40 for each takes Base 24, for example on a metal plate, to a new copy to be made by a certain amount closed. To the surface 16 of the photoconductive too, because the electrostatic forces which the toner layer with a uniform negative charge to hold particles on the surface 16, with delays, the recording material 10 will increase with the thickness of the toner particle layer, its layer carrier 12 is placed on the plate 24 35 Furthermore, the charge image also sounds in the course of time and the surface 16 thus of the negative corona and each newly developed image therefore contains one discharge suspended. smaller amount of toner particles than the previous

According to FIG. 3 now becomes a charge image. However, in accordance with a light image on the surface 16, six copies of the same were produced one after the other without difficulty. For this purpose, this surface 16 40 is made to contrast with the use of steel rollers 38 and 40 through a transparency 28 to the light of a lamp with the following voltages:
26 exposed. The transparency 28 can be a

Be a photograph made from a pattern of light- 1. Copy 600 V

permeable and translucent places. 2nd copy 650 V

The evenly charged surface 16 then becomes 45 3 copy 750 volts

selectively by discharging the charges through the photographic. ' . "" _{Q £} - _{n Λ /}

conductive layer 14 and the conductive base 12 ⁴ "^ ⁰ ? ^ ^{85υ ν}

in the exposed areas corresponding to the inten- 5. Copy 1000 V

sity of the exposure, so that a charge image 6th copy 1200 V

remains on the surface 16. 50

According to FIG. 4, the charge image can now be selected by means of at least one of the rollers 38 and 40

a developer 30 is made of conductive rubber developed into a toner image, the stresses

which, for example, from a mixture of considerably reduce, and probably the-

electroscopic toner particles and iron filings half because rubber rollers make better contact

consists. The toner of the developer 30 can produce the 55. It was only 10%

Charge image with the aid of a magnet 32 according to the voltages given above, if required

U.S. Patent 2,874,063. at least one of the conductive rubber rollers

A copy of the unfixed toner image can also exist.

by means of the in F i g. The device shown in FIG. 5 is obtained in FIG. 6 is a device 50 for fully autowerden. An image receiving material 34, for example 60, automatically carries out the production of copies a sheet of paper, is illustrated with its underside 36 on the. A tape-shaped recording surface 16 is placed so that the underside 36 contains the material 52, similar to the recording material 10 Unfused toner image touched. The image and photoconductive coating 86 is then passed through receiving material 34 and the recording material from a supply reel 54 a predetermined path between two rollers 38 and 40 firmly on top of one another 65 up to a take-up reel 56. It happens the pressed. The rollers 38 and 40 consist of electrical rollers 58, 60 and 62.

Trically conductive material, for example made of steel or between the supply roll 54 and the roller 58

conductive rubber. are charging and exposure devices 64 and 64

66 arranged. A plurality of developing devices 70 D, 72 D, 74 D, 76 D, 78 D and 8OD and a plurality of image transfer devices 70 T, 72 T, 74 T, 76 T, 78 and 80 T are provided along this path. An image eraser 82 is located between rollers 60 and 62.

In the charging station 64, the surface of the photoconductive zinc oxide layer 86 of the recording material 52 uniformly negatively charged, for example by a known double charging device 88. To this end, the device 90 is connected to the negative terminal of a not shown suitable voltage source connected, and on the underside of the recording material 52 charging device 92 located at this point is connected to the positive terminal of this voltage source. The surface 86 is thus negatively charged.

This uniformly charged tape-shaped recording material 52 then travels in the exposure station 66 in front of the screen of a cathode ray tube 94 in order to be exposed imagewise through its screen image.

A thin band of transparent plastic 96 is arranged between the recording material 52 and the screen of the cathode ray tube 94 and moves much more slowly than this in order to avoid excessive wear to the faceplate of the screen by the recording material 52. The plastic tape 96 is unwound from a reel 98, passes a guide roller 100, then the faceplate of the screen, whereupon it is picked up again by a take-up reel 102. During the exposure at the cathode ray tube 94, the recording material is discharged in accordance with the imagewise exposure, so that the desired charge image is produced. The exposure time is relatively short compared to the belt speed, so that the recording material can be exposed with continuous movement.

The charge image on surface 86 of recording material 52 is then transferred to the development station 70D developed by the development facility 7OC. The details of this development facility 70 C are in FIG. 7 shown.

In this Figure 7, the developing device designated as a whole by 7OC contains a container 106, in which there is a supply of electroscopic developer powder 108. This developer powder can consist of toner particles and iron filings. The developer powder is by means of of a wide belt 110 with the photoconductive surface 86 of the recording material 52 in Brought in touch. The belt 110, which can consist of a fabric, wraps around the rollers 112 and 114. A roller-shaped brush 116 with relatively soft hair or made of one flexible metal is self-propelled so that it connects the belt 110 and the recording material 52 touched. Two metal rollers 118 and 120 rotate below the poles of an electromagnet and serve for a purpose yet to be explained. An electromagnet 124 has its two poles above the roller 112 and the brush 116 and serves to also be explained further below Purpose. A motor 126 drives the roller 112, the brush 116 and the rollers 118 and 120 by means of one Belt 128 so that these rollers or the brush in the directions indicated by the arrows circulate.

In operation, the developer powder 108 is applied to the recording material 52 by the belt 110 transfer. At this time, the magnetic particles of the developer 108 are driven by the electromagnet 124 attracted and pressed against the recording material 52. Part of the toner particles and part

ίο the magnetic particles remain on the recording material 52 adhere and migrate to the brush 116. This brush 116 runs at a slower speed around than it corresponds to the throughput speed of the recording material and leads additionally Developer to the recording material 52 to. This is because of the speed difference between the recording material 52 and the brush 116, the developer powder 108 of the surface 86 of the recording material 52 is fed so that the charge image is developed. Any magnetic Particles that may still be present on surface 86 after the image has been developed, are removed by rollers 108 and 120. The electromagnet 122 forms a magnetic one Circle over rollers 118 and 120, as indicated by a dotted line in FTg: 7, so that the aforementioned magnetic particles are removed from the photoconductive surface 86 and into the vessel 106 are returned.

After leaving the developing device 7OD, the recording material 52 migrates to the image transfer point 70 T between the pressure rollers 70 , 4 and 70 B. These rollers correspond in their mode of operation to the rollers 38 and 40 in FIG.

They are driven in a suitable manner and feed an image receiving material 705, for example a sheet of paper, at the speed of the recording material 52, and bring it into contact with the toner image, so that the image receiving material is rolled on the toner image in the nip, with the unfixed toner image continuously is transferred from the recording material 52 to the image receiving material 705. The roller 70.4 is at a voltage of the polarity of the toner opposite polarity. The copy thus obtained can be fixed by heating then, as indicated by the wavy lines 70 H. Further copies are made by developing the original charge image again and transferring the toner image to another image-receiving material. One can thus, the original charge image in the successive development stations 72 D to 80D by appropriate devices 72 C to 80C again develop and transmitted between the rolls 72.4 and 72 B to 80.4 and 80 B to image receiving materials 72 5-805. The voltages between the rolls 72.4 and 72 B to 80.4 and 80S to take out of place. According to the on the basis of FIG. The explanations given in FIGS. 2 to 5 can thus produce a plurality of copies with practically the same contrast if the same developer 108 is used for each copy. If one wants to use different developers for the different copies, each transfer voltage must be chosen accordingly. For example, electroscopic developer mixtures with different toner particles (for example from different

7 8

different colors) and iron filings different charge patterns are created. The speed of the attributional electric charges, which then the drawing material 152 assume, is relatively small compared to the exposure of differently large transfer voltages at the time of generation, so that the recording of copies of a desired contrast requires voltage material 152 uniformly on the screen. 5 188 can walk by without blurring images

Having to worry about having the desired number of copies.

is produced, an approximately amount of toner remaining on the recording The charge image is then developed and transfer material 52 carry in one. In facility 150 , three developer-cleaning stations 82 have been removed. A suction and transfer stations 71, 73 and 75 display device 134 which are attached to a vacuum system. Of course, one can also use a larger one, as shown in Fig. 6 is due to the number of such stations recorded.
material 52 to remove the excess toner particles. Stations 71, 73 and 75 are among themselves to be removed from the charge image. The suction pre-formed. Therefore, in stations 73 and direction 134 , the parts corresponding to station 71 with brushes, but which are not shown, are also equipped with rotating cleaning 75, the same reference numerals with the addition of the letters, in order to ben α and b indicated,
support. The development facility 77 of station 71

In Fig. 8 is another complete with 150 contains a revolving brush 81, for example shown embodiment for the production of a cylinder covered with velvet in a vessel multiple copies by means of multiple developer 20 83 which is filled with developer powder 85. A spreading of a charge image and transfer of the belt 87 between the rollers 89 and 91 is used for the toner image of the photoconductive surface 186 of a subsequent delivery of toner particles 93 into the developing recording material 152 on image receiving material powder 85. The relevant supply of toner particles is shown. The recording material 152 is located in a funnel 95 and can then be provided with a substrate of suitable conductivity if it is consumed with a moist toner during the development of the charge image, for example from paper. A vibrator is included with the speed content of about 5 to 6%, and the photo funnel 95 is mechanically coupled and ensures that the conductive surface of the belt can be made of zinc oxide so that the toner particles 93 stick down onto the belt 87. The tape-shaped recording material falls.

152 is driven by a motor 104 along a 3 ° The belt 87 is driven by a motor,

written path from a supply roll 154 to that with one of the two rolls 89 or 91 coupled

a take-up roll 156 promoted. It's going through. The belt 87 is arranged so that it is the brush

So the rollers 136 and 138, then wraps around the 81 touches, which in turn touches the charge image on the

Rollers 158 and 160 then run between the roll surfaces 186 by feeding toner particles

zen 140 and 142 and then reaches 35 developed. Any magnetic particles like that

Take-up roller 156. Iron filings of the developer powder 85, which on

A charging station 164, and an image exposure of the photoconductive surface 186 by the through station 166 between the rollers 138 and 158. guide the development of sticking, to be between the rollers 158 and 160 are three development stations RoI by a magnetic system with the iron 71 , 73 and 75 are provided, select 99 and 101 and, by means of a magnet 103, a cleaning station 46 is removed between the rollers. Rollers 99 and 101 are placed on appropriate 160 and 140 rests. In a practical embodiment driven way. Since these roles are closer to that of FIG. In the embodiment shown in FIG. 8, if the photoconductive surface 186 is located as the Madas recording material 152 moves at a speed 103, the magnetic particles are at a rate of about 2500 cm per minute. 45 rollers 99 and 101 tightened and removed from the magnetic

The belt 152 is evenly charged out in the charging station 164 table field as these rollers rotate. A negative lead is used for this purpose. They then fall onto the brush 81 or onto the corona device 190, preferably onto the photographic belt 87, and return to the developer powder 85 conductive surface 186 of the recording material in the vessel 83 . After developing the rial and a positive corona device 192 on 50 charge image, the unfixed toner image is on one side of the substrate. The means 190 of image receiving material within the transfer and 192 include a double corona means 79 transfer. The transfer device is known in itself. When the terminals 144 and 79 contain two electrically conductive rollers 105, 146 of the devices 190 and 192 with the negative and 107, which are arranged on the two sides of the belt-shaped and the positive terminal a voltage source of 55 recording material 152 . The approximately 6000VoIt are connected, the photo roller 107 is grounded, and the roller 105 is charged on the one conductive surface 186 negatively with respect to the lei terminal 109 of a transmission voltage source antenden layer support. closed, the other terminal of which is also closed

In the image exposure station 166 , image is grounded by.

moderate exposure of the photoconductive layer on the 60. The rollers 105 and 107 are mechanically

Screen of a cathode ray tube 194, like a niche means, for example by springs, on one-

in the journal RCA Review, Volume XXII, Issue 3, differently pressed, so that the recording material

S. 582 ff, September 1961 is described, a La- 152 pressed against the image receiving material 111

generated image. When that becomes evenly charged. At least one of the rollers 105 and 107 , recording material 152 on the screen 188 65 can be made of conductive rubber to ensure good contact.

Passing by, the photoconductive surface 186 will ensure pressure. The image receiving material

rendered conductive by the light, so that in the areas 111 may have the shape of a long strip,

cleared areas the charge flows off and one which is unwound from a supply roll 113,

ino cot; 10 m

the roller 105 wraps around and thus comes into contact with the unfixed toner image on the photoconductive surface 186 of the recording material 152. The motor 104 is mechanically coupled to the roller 107 , which in turn can be coupled to the roller 105 to advance the image receiving material 111 at the same speed as the recording material 152 has. The motor 104 is also coupled to the rollers 107 a and 107 &. Part of the toner is thus transferred from the unfixed toner image to the image receiving material 111 , on which the first copy of the image is then produced, which can then be fixed, for example by means of heat rays 115.

The amount of the electroscopic toner which is transferred from an unfixed toner image to the image receiving material 111 can be influenced by a transfer voltage which is between the rollers 105 and 107 , that is, between the image receiving material 111 and the recording material 152 . with which the charge image was developed is negative, the greater the positive voltage on roller 105 with respect to earth, the greater the proportion of the negative toner particles is transferred.

Further copies can on image-receiving materials purple and 111 b by a further development of the charge image on the photoconductive surface 186 inside of the developing devices 77 a and 77 b and are made by transfer of the unfixed toner particles of newly developed toner image.

Since the charge of the charge image decays in the course of time, a constant contrast of the successive copies is ensured by applying a transfer voltage which varies from copy to copy to the terminals 109 a and 109 b. When using the same type of developer 85 for all copying processes, the transfer voltage

ίο be increased from copy to copy in order to obtain the same contrast values. The voltage at terminals 109 a and 109 b can be, for example, 650 and 750 volts when a voltage of 600 volts is applied to terminal 109.

Instead of the in FIG. 8, more than three additional development stations can also be arranged along the path of the recording material 152. The three transfer stations 71, 73 and 75 shown in FIG. Practical tests have shown that it is easy to make six copies of the same charge image.

After the desired number of copies have been made, the remainder of the toner still on the photoconductive surface 186 is removed by the cleaning device 46. This cleaning device essentially contains a suction device with the brushes 117, 119, 121 and 123, which are driven within the housing 125 . The cleaned recording material tape 152 is then wound onto the take-up reel 156 and can be used again.

For this purpose 2 sheets of drawings

Claims (3)

Patent claims: 1. Electrophotographic process for making multiple copies, in which a charge image generated, developed with a toner, the toner image in an electric field on a Image receiving material is transferred and the charge image is redeveloped for each additional copy and transferring the toner image to another image receiving material in an electric field is, characterized in that the transfer of the toner images takes place with increasing field strength from copy to copy. 2. Copier for performing the method according to claim 1 with a device for generating a charge image on an electrophotographic recording material and a plurality of alternately successive development and toner image transfer devices, characterized in that each toner image transfer device has two electrically conductive rollers (7OA, 7OB ... SO A, 8OB; 105, 107 ... 105 b, 107 b) which are connected to voltage sources which supply voltages which increase from toner image transfer device to toner image transfer device. 3. Device according to claim 2, characterized in that at least one of the two Rollers made of conductive rubber.