JPH01251062A - Image forming device - Google Patents

Abstract

PURPOSE:To erase an unnecessary black image which appears on a part other than the image of an original by detecting a dark part by means of reflected light from an original surface by scanning and removing charges on a corresponding photosensitive body. CONSTITUTION:A dark part detector 180 is movably provided between a lens block 8 for variable magnification and a mirror 9 as a detection means for detecting the dark part by means of the reflected light from the original surface. The reflected light from the original surface by the photoirradiation of an exposing lamp 4 is received by a line sensor 131. An output from the line sensor 131 is utilized to identify a black area on image information, so that an area where the original does not exist is detected as the dark part and the surface charges of the photosensitive drum corresponding to the outer side from the marginal part of the original are removed. Thus, the unnecessary black image which appears on the part other than the image of the original can be erased and the quality of a copied image can be improved.

Description

DETAILED DESCRIPTION OF THE INVENTION [Object of the Invention] (Industrial Application Field) The present invention relates to an image forming apparatus applied to, for example, an electronic copying machine.

(Prior Art) In an image forming apparatus, for example, an electronic copying machine using an electrophotographic process, a document placed on a document table is covered with a document cover from above, and an exposure lamp that irradiates objects other than MgJ is covered by the document cover. By guiding this light to the photoreceptor drum, unnecessary charges remaining on the surface of the photoreceptor drum are removed.

However, if the document is scanned with the document cover left open, the light from the exposure lamp that illuminates areas other than the document will not form an image on the photoreceptor drum. In this case, unnecessary charges around the original image are not removed, and toner is deposited on areas other than the original image during subsequent development.

For this reason, if the original size is smaller than the paper size, or even if the original size and paper size are equal, the copy size due to reduction may be smaller than the paper size, or the original may be tilted and placed incorrectly on the document table. In some cases, the area around the M draft image of a copy image becomes pitch black due to toner. Further, in the case of a thick original such as a book, the original cover does not completely contact the original table, so that unnecessary black images due to shadows are generated around the original image in the copied image.

In this way, if an unnecessary black image (solid black image) appears around the original image due to wasted toner, the reproduced image is not aesthetically pleasing and is of poor quality. There was a problem that the agent was consumed rapidly.

(Problems to be Solved by the Invention) This invention solves the problem that if an image forming operation is performed with the document cover not completely closed, unnecessary black images will be generated in areas other than the document image. This was done to eliminate the disadvantages that the quality of the copied image is poor and the amount of developer is wasted, and the image formation operation is performed with the document cover not completely closed. To provide an image forming device capable of erasing an unnecessary black image appearing in a part other than an original image, improving the quality of a copied image, and preventing wasteful consumption of developer even when the original image is The purpose is to

[Structure of the Invention] (Means for Solving the Problems) In the image forming apparatus of the present invention, a photoreceptor is charged by optically scanning a document placed on a document table with an optical system. In an image forming apparatus that forms an image corresponding to an image of an original document, develops this image, and transfers it to a transfer material, a detection means detects a dark part from light reflected from the original surface by scanning with the optical system; and a removing means for removing the charge on the photoreceptor corresponding to the dark area detected by the detecting means.

(Function) This invention detects dark areas (non-reflective areas) from light reflected from the document surface by scanning an optical system and removes the charge on the corresponding photoreceptor, thereby creating an image that appears in areas other than the original image. It is designed to erase the .

(Example) Hereinafter, an example of the present invention will be described with reference to the drawings.

FIGS. 1 and 2 schematically show an image forming apparatus of the present invention, such as a copying machine. A document table (transparent glass) 2 for supporting a document is fixed to the top surface of the copying machine main body 1. This document table 2 is provided with a fixed scale 21 that serves as a reference for setting the document, and near the document table 2 is a document cover 11 that can be opened and closed, and the open/closed state of the document cover 11 is detected by a magnet and a reed switch. A cover detection switch 600 is provided. and,
The original placed on the original platen 2 is exposed and scanned by an optical system consisting of an exposure lamp 4 and mirrors 5, 6.7, which is reciprocated along the lower surface of the original platen 2 in the direction of arrow a. It looks like this. In this case, mirror 6.7 is moved at half the speed of mirror 5 so as to maintain the optical path length. The light reflected from the original by the scanning of the optical system, that is, the light reflected from the original by the light irradiation of the exposure lamp 4, is reflected by the mirrors 5, 6.7, passes through the variable magnification lens block 8, and then passes through the mirror. 9 and guided to the photoreceptor drum 10, so that an image of the document is formed on the surface of the photoreceptor drum 10.

The photosensitive drum 10 is rotated in the direction of the arrow C shown in the figure, and the surface thereof is first charged by the charging device 11 . Thereafter, the image is subjected to slit exposure in the exposure section ph, thereby forming an electrostatic latent image on the surface. This electrostatic latent image is made visible by applying toner by the developing device 12.

On the other hand, the paper (transfer material) P is taken out one by one from the selected upper paper feed cassette 13 or lower paper feed cassette 14 by the delivery roller 15 or 16, and the taken out paper P is transferred to the paper guide path. 17 or 18, and is guided to a pair of registration rollers 19, and sent to the transfer section by one pair of registration rollers.

Here, the paper feed cassettes 13 and 14 are removably provided at the lower right end of the main body 1, and one of them can be selected from an operation panel to be described later.

The cassette size of each of the paper feed cassettes 13 and 14 is detected by a cassette size detection switch 01.602. The cassette size detection switches 601 and 602 are composed of a plurality of microswitches that are turned on and off according to the insertion of cassettes of different sizes.

The paper P sent to the transfer section is brought into close contact with the surface of the photoreceptor drum 10 at the transfer charger 20, and
The toner image on the photoreceptor drum 10 is transferred by the action of 0. The transferred paper P is electrostatically peeled off from the photosensitive drum 10 by the action of a peeling charger 21, and is sent by a conveyor belt 22 to a fixing roller 23 as a fixing device provided at the end thereof. The transferred image is fixed by passing through this, and the fixed paper P is discharged to a tray 25 outside the main body 1 by a pair of paper discharge rollers 24 .

Further, the photoreceptor drum 10 after the transfer is transferred to a charger 26 for removing static electricity.
After the charge is removed by the cleaner 27, residual toner on the surface is removed, and the afterimage is erased by the charge removal lamp 28, so that the initial state is restored. Note that two cooling fans are used to prevent a rise in temperature within the main body l.

FIG. 3 shows an operation panel 30 provided on the main body 1. 30a is a copy key for commanding the start of copying, 30b
is a numeric keypad for setting the number of copies, etc.; 30c is a display unit that displays the operating status of each part and paper jams; and 30d
30e is the count command key for displaying the total number of copies, and 30f is the ID copy mode that allows copying only when the identification codes (ID codes) match. ID for displaying the number of copies corresponding to each ID code.
It is a count key.

In addition, 30g is an edit key that is operated when performing multiple copying, etc. to erase an unnecessary black image (black frame) that appears around the original image of the copy image (transfer image) formed on paper P, and 30h is Magnification setting key operated when setting copy magnification, 30i is upper and lower paper feed cassette 13.1
The cassette selection key 30 is operated when selecting item 4, for example, if the edit key 30g is operated and copy conditions etc. are set in this state, the set copy conditions etc. can be memorized or stored in advance. The mode memory key 30J2 is operated to read out copying conditions etc., and the information key 30J2 is operated to obtain information corresponding to each mode.For example, if a paper jam occurs, operating this key 30J2 Information for clearing the jam is displayed on a display 30o, which will be described later.

Furthermore, 30m is a function check 'r-, and when this function check key 30m is operated, the display 30o shows what function is set.
can be displayed.

30n is a dial for adjusting the contrast of the display 30o. Reference numeral 300 denotes a display device consisting of, for example, a liquid crystal dot matrix panel, and the display device 30o displays the setting status of the copying machine using characters, etc., and the various keys 30e.

When 30f, 30g to 30m are operated, the corresponding characters are displayed.

On both sides of the display 30o are operation keys 301 to 304, 30 for selecting various functions displayed on the display 30o.
For example, when the operation key 304 is operated in the illustrated state in which "mark eraser" is displayed on the display 30o, the copying machine is set to the automatic mark eraser mode. ing.

FIG. 4 shows an example of the drive source configuration of each drive unit of the copying machine configured as described above, and is composed of the following motors. That is, 31 is a lens motor, which is a motor for moving the position of the lens block 8 in the direction indicated by the arrow in the figure for performing magnification change. 32 is a mirror motor, which is a motor for changing the distance (optical path length) between the mirror 5 and the mirror 6.7 for changing the magnification. 33 is a scanning motor, which is a motor for moving the exposure lamp 4, mirror 5, and mirror 6°7 for scanning the original; 34 is a shutter motor, which moves the photosensitive drum during magnification change; This is a motor for moving a shutter (not shown) for adjusting the charging width of the charger 11 on the charger 10 . A developing motor 35 is a motor for driving the developing roller of the developing device 12 and the like. 36 is a drum motor, which is a motor for driving the photosensitive drum 10. 37 is a fixing motor, which connects the paper conveyance path 22.
, a motor for driving the pair of fixing rollers 23 and the pair of paper ejection rollers 24. 38 is a paper feeding motor, which is a motor for driving the delivery rollers 15 and 16.

39 is a paper feed motor, and the registration roller pair 1
This is a motor for driving 9. A fan motor 40 is a motor for driving the cooling fan 29.

FIG. 5 shows a drive mechanism for reciprocating the optical system. That is, the mirror 5 and the exposure lamp 4 are supported by a first carriage 411, and the mirror 6.7 is supported by a second carriage 412, respectively, and these carriages 411, 412 are guided by guide rails 421, 422 in the direction of arrow a. It is said to be able to move in parallel. Also,
The four-phase pulse motor 33 drives a pulley 43. An endless belt 45 is stretched between the pulley 43 and the idle pulley 44.
One end of a first carriage 411 that supports the mirror 5 is fixed in the middle of the mirror.

On the other hand, two pulleys 47, 47 are rotatably provided in the guide section 46 of the second carriage 412 that supports the mirror 6.7, spaced apart in the axial direction of the rail 422. A wire 48 is strung around.

One end of this wire 48 is fixed to a fixed part 49, and the other end is fixed to the fixed part 49 via a coil spring 50. Further, one end of a first carriage 411 is fixed to a midway portion of the wire 48. Therefore, as the pulse motor 33 is rotated, the belt 45 is rotated and the first carriage 411 is moved, and the second carriage 412 is also moved accordingly. At this time,
Since the pulleys 47, 47 function as movable pulleys, the second carriage 412 is moved in the same direction at half the speed of the first carriage 411. In addition, 1. The direction of movement of the second carriage 411, 412 is determined by the pulse motor 33.
It is controlled by switching the direction of rotation.

Further, on the document table 2, a copyable range corresponding to the specified paper is displayed. In other words, cassette selection key 3
If the paper size specified by 0i is (Px, Py) and the copy magnification specified by the magnification setting key 30h is K, then the copyable range (x, y) is 1-x=Px
/K”.

This copyable range (x, y) becomes “y=Py/K”
In the X direction, a pointer 51 provided on the back side of the document table 2
．． 52, and the y direction is indicated by a scale 53 provided on the upper surface of the first carriage 411.
and the fixed scale 21.

The above-mentioned pointers 51 and 52 are connected to the pulley 54
, 55 via a spring 56. The pulley 55 is a motor 58
This motor 58
is driven in accordance with the determined copyable range in the X direction, thereby changing the distance between the hands 51 and 52.

Further, the first carriage 411 is moved to a predetermined position (home position according to the magnification) by driving the motor 33 according to the paper size and the copy magnification. In the normal copy mode, when the copy key 30a is operated, the first Ir carriage 411 is first moved in the direction of the second carriage,
After that, the exposure lamp 4 is turned on and the second carriage 411
is moved in the direction away from. When scanning of the original is completed in this way, the lamp 4 is turned off and the first carriage 411 is returned to the home position.

On the other hand, the mark erasing mode is specified and the document cover 1
When the copy key 30a is operated while the copy key 1 remains open, the first carriage 411 is moved from the home position HP according to the magnification toward the second carriage 412, as shown by al in FIG. Ru. Then, the exposure lamp 4 is turned on, and the second carriage 4 is turned on, as shown by a2 in the figure.
12, and a preliminary scan is performed for light/dark discrimination in which dark areas (non-reflective areas) are detected from light reflected from the document surface. When this preliminary scanning of the document is completed, the lamp 4 is turned off, and the first carriage 411 is moved toward the second carriage 412, as shown at a3 in the figure. Then, the exposure lamp 4 is turned on again and moved in a direction away from the second carriage 412 as shown by a4 in the figure, thereby performing scanning for image formation (main scanning). When the main scanning of the document is completed, the lamp 4 is turned off and the first carriage 411 returns to the home position H.
Returned to P.

FIG. 7 shows the overall control circuit.

The main processor group 71 includes a high-voltage transformer 76 that detects inputs from the operation panel 30 and input devices 75 such as various switches and sensors, such as the cassette size detection switches 601 and 602, and drives the various chargers;
the static elimination lamp 28, the blade solenoid 27a of the cleaner 27, the heater 23a of the fixing roller pair 23,
The exposure lamp 4 and each of the motors 31 to 40.5
8 etc. to perform the above-mentioned copying operation, and also control the line sensor 131, pulse motor 135, bitmap memory (image memory) 140, erase array 150, array drive section 160, image processing section 170, etc. using the operation panel. 30 and an input device 75 such as the cover detection switch 600, and performs an operation to erase unnecessary black images appearing around the original image of the copy image. Note that the line sensor 131, pulse motor 135, bitmap memory 140, and erase array 15
0, the array driving section 160, and the image processing section 170 will be described later.

Among the above motors 31 to 40.58, motor 35.37
．． A toner motor 77 that supplies toner to the developing unit 40 and the developing device 12 is controlled by the main processor group 71 via a motor driver 78.
are controlled by the first sub-processor group 72 via seven pulse motor drivers, and the motors 36, 39, 38, 58
is controlled by the second sub-processor group 73 via the pulse motor driver 80. Further, the exposure lamp 4 is controlled by the main processor group 71 via the lamp regulator 81, and the heater 23a is controlled by the main processor group 71 via the heater control section 82. The main processor group 71 to the first and second sub-processor groups 72.7
Drive/stop commands for each motor are sent to the first motor. Second
From sub-processor group 72 and 73 to main processor group 7
1, a status signal indicating the drive/stop state of each motor is sent. Further, the first sub-processor group 72 receives position information from a position sensor 83 that detects the initial positions of the motors 31 to 34, 135. These first
．． The second sub-processor group 72, 73 includes, for example, a microcomputer and a programmable interval timer that counts reference clock pulses according to a set value supplied from the microcomputer and controls the phase switching interval time of the pulse motor. It is made up of.

Next, a detection means for detecting dark areas (non-reflective areas) from light reflected from the document surface will be described. In FIGS. 1 and 8, for example, a dark area detector 180 is movably provided between the entire borrowed lens block 8 and the mirror 9. The dark area detector 180 includes a line sensor 131 that receives reflected light from the document surface and outputs image information corresponding to the reflected light, and an atlens 181 that forms an image of the reflected light from the document surface on the line sensor 131. It consists of For example, a convex lens is used as the at-lens 181 in order to supplement the optical path length of the reflected light from the document surface.

Further, FIG. 8 shows a drive mechanism for moving the dark area detector 180. That is, the atlens 181 and the line sensor 131 are arranged on a base 182, and this base 182 is connected to the guide rails 183, 1
83 so that it can freely move in parallel in the direction of arrow d in the figure. Furthermore, an endless belt 1 is attached to one end of the base 182.
86 is fixed. This endless belt 186 is stretched between a pulley 184 and an idle pulley 185, and the pulley 184 is driven by a pulse motor 135 to
It is designed to rotate in the opposite direction. Therefore, when the pulse motor 135 is rotated in the forward direction, the base 182 is moved by the rotation of the belt 186, and the dark area detector 180 is thereby moved when detecting a dark area.
is moved into the optical path between the lens block 8 and mirror 9. In this position, as shown in FIG. 9, the light reflected from the document surface by the light irradiation of the exposure lamp 4 that has passed through the variable magnification lens block 8 is imaged on the line sensor 131 by the atlens 181. ing. In this case, the at-lens 181 and the line sensor 131 are arranged on the same base 182, so that the at-lens 181 and the line sensor 131 are moved simultaneously.

This eliminates the need for delicate positioning and F1 adjustment because no deviation occurs in the optical path.

Further, when the pulse motor 135 is rotated in the opposite direction, the base 182 is moved out of the optical path by the rotation of the belt 186, and in this position, the light reflected from the original surface by the light irradiation of the exposure lamp 4 is reflected on the mirror 9. The light is reflected by the light and formed into an image on the surface of the photoreceptor drum IO. That is, by retracting the dark area detector 180 from the optical path during the image forming operation, the size of the projected area occupied by the at-lens 181 and the line sensor 131 does not affect the image forming operation.

A protrusion 187 is provided at one end of the belt 186, and when this protrusion 187 comes into contact with a position sensor 83 consisting of, for example, a microswitch, the initial position of the pulse motor 135 is detected. It has become.

Here, the operation of detecting dark areas (non-reflective areas) from light reflected from the document surface using the dark area detector 180 will be described. This dark area detector 180 has, for example, a mode designated as "automatic mark removal", and the CC cover 11
When the copy key 30a is operated in the open state, the variable magnification lens 10 is moved into the light n between the knob 8 and the mirror 9. That is, in response to the operation of the copy key 30a, it is determined that the mark erasing mode is designated by the operation of the edit key 30g and the operation key 304, and the cover detection switch 600 determines that the document cover 11 is not completely closed. When this is detected, the motor 135 is first driven.

Then, by driving the motor 135 from the initial position, the base 182 is moved a predetermined distance in a direction perpendicular to the optical path, and the atrens 181 and line sensor 131 are positioned on the optical path.Then, the motor 33 is driven. , 1st carriage 41! is moved in the direction (al) of the second carriage 412 from the home position HP. Then, the exposure lamp 4 is turned on, and the first carriage 41r is moved in the direction (a2) away from the second carriage 412, thereby performing preliminary scanning for bright/dark discrimination. Therefore, the reflected light from the document surface due to the preliminary scanning is reflected by the mirror 5.6.7, is supplied to the dark area detector 180 via the variable magnification lens block 8, and is imaged on the line sensor 131 by the atlens 181. be done.

In this way, the reflected light from the document surface that is imaged on the line sensor 131 is output as image information. The output (image information) of this line sensor 131 is transmitted to the image processing section 1
At 70, each pixel is binarized according to a preset threshold value to identify whether each pixel is bright (white pixel) or dark (black pixel). The results of this identification are scanned and stored in the bitmap memory 140 by the main processor group 71 as identification data in which brightness is set to low level and darkness is set to high level. This memory 140 has a capacity slightly larger than the maximum M document size that can be copied, and has low/low/dark settings for each pixel of image information depending on brightness/darkness.
High level signals are stored. Therefore, for example, as shown in FIG. 10, when preliminary scanning is performed with the document G placed on the document table 2 obliquely with respect to the scanning direction, the memory 14 as shown in FIG.
0, a bitmap is formed in which the periphery (non-image area) of the original (original image area) G is at a high level (hatched area in the figure). That is, if the document G is irradiated with light from the exposure lamp 4 while the document cover 11 is not completely closed, the light irradiated around the document G will be exposed to the document cover 11.
The area other than document G is a non-reflective area (black area).
It is now detected as . By defining this non-reflective area as a dark area using a predetermined threshold value, a non-image area where the original MG does not exist is detected by light reflected from the document surface. For this detected non-image area, by storing a high level signal such that the scanning direction of the document is perpendicular to the column direction of the memory 140, a dark area as shown in FIG. 11 is stored in the memory 140 as a bitmap. It is formed.

By the way, if you simply define the non-reflective area as a dark area and perform the erase operation described later, for example, if there is a black area (black solid) on the image of document G, this black solid will also be detected as a dark area. The required image (
black solid, etc.)! However, in order to eliminate the above-mentioned problems, the image processing section 170 performs a simple pattern recognition process to erase only non-image areas other than the original image. form a bitmap. That is, in response to the bright or dark identification result, the image processing unit 170 labels a label that leaves a black pixel surrounded by white pixels, that is, a high level signal surrounded by low level signals as a low level. Attachment processing (labeling processing) etc. is performed. As a result, a bitmap is created in which high-level signals are stored only in non-image areas, regardless of the presence or absence of necessary black solids on the image, so dark areas outside the edges of the original image are erased. A range will be set.

Next, the photosensitive drum 1 corresponding to the dark area determined above is
A removal means for removing zero surface charges will be explained. As shown in FIG. 12, an erasing array 150 is provided adjacently between the charger 11 of the photosensitive drum 10 and the exposure section ph. As shown in FIGS. 13 and 14, this erasing array 150 includes a plurality of light-shielding cells 151 arranged in a direction perpendicular to the rotational direction of the photoreceptor drum 10, and each light-shielding cell 151 has a Figure 15(a),
A light emitting element 152 made of, for example, a light emitting diode is provided as shown in FIG.

Furthermore, a lens 153 that focuses the light from the light emitting element 152 onto the surface of the photoreceptor drum 10 is provided in the opening of each cell 151 facing the photoreceptor drum 10 . The number of light emitting elements 152 arranged in this erasing array 150 matches, for example, the capacity of the memory 140 in the column direction.

Here, if the distance between the light emitting elements 152 is Pl and the number is N, the total length of the erasing array 150 is Q=NXPt
becomes.

The erase array 150 is driven by the array driver 160 described above. This array driving section 160 is the 16th
As shown in the figure, a shift register 161 having the same number of bits as the number of bits in the column direction of the memory 140, and a store register 1 in which the contents of this shift register 161 are held.
62, it is constituted by a switch circuit 164 consisting of a plurality of switch elements 163 that are turned on/off and controlled by each output signal of this store register 162, and the movable contact pieces 163a of these switch elements 163 are grounded.
The fixed contacts 163b are connected to each cathode of the light emitting elements 152 constituting the erasing array 150, respectively.

The anode of each of these light emitting elements 152 is a current limiting resistor R
are connected to the power supply Vcc through the respective terminals.

As described above, after the dark area (erasure range), which is a non-image area, is detected from the light reflected from the document surface during preliminary scanning, the motor 135 is driven and the dark area detector 180 is moved out of the optical path. Further, as the first Ir cartridge 411, photosensitive drum 10, etc. are operated, one column of data is sequentially read out from the memory 140 in the row direction (as shown in FIG. 11). This read data D is transferred to the shift register 161 of the array driving section 160 in response to the clock signal CLK. shift register 161
When the charged portion of the photosensitive drum 10 reaches the erase array 150 after one column of data has been transferred, the main processor group 71 outputs a relatch signal LTH.
The data stored in shift register 161 is supplied to store register 162 in response to signal LTH. That is,
Since the erasing array 150 is arranged between the charger 11 and the exposure section ph, one column of data output from the memory 140 has, for example, an angle of θ1 between the erasing array 150 and the exposure section ph, and The photosensitive drum 10 has an angular velocity ω
Assuming that the latch signal LTH is rotating at .theta.1/.omega., the output timing of the latch signal LTH is controlled so that it is supplied to the store register 162 before .theta.1/.omega..

Each switch element 163 of the switch circuit 164 is controlled by the output signal of the store register 162. That is, when the output level of the store register 162 is high level, it is turned on, and when it is low level, it is turned off. As a result, the light emitting elements 152 connected to each switch element 163 are turned on when the switch element 163 is on, and are turned off when the switch element 163 is off. Therefore, among the charged parts of the photoreceptor drum 10, the part where the light emitting element 152 is turned on is charge-free, and even if the charge-free part is subsequently exposed, no electrostatic latent image is formed, and the image is erased. become. In this way, the lighting of the light emitting elements 152 of the erasing array 150 is controlled in accordance with the non-image area.
Thereafter, data in the memory 140 is read out one column at a time in the same manner, thereby erasing unnecessary black images appearing around the original image.

Next, the operation of the above configuration will be explained with reference to the flowchart shown in FIG. 17. For example, now, a document G is placed on the document table 2, and the copy key 30a of the operation panel 30 is pressed.
is input (STI), then the edit key 30
g and the operation key 304, it is determined whether or not the "erase" mode is designated (ST2).
.

In this step (ST)2, if it is determined that the mark erasing mode is designated, it is determined whether or not the document cover 11 remains open based on the input from the cover detection switch 600 (ST3); That is, if the copy key 30a is operated while the mark erasing mode is specified and the document cover 11 is not completely closed, the process moves to step (ST) 4, and in the subsequent steps, the periphery of the document image is The unnecessary black image that appears is erased.

In this step 4, the motor 13 is
5 is driven in the forward direction, and by driving the motor 135 from the initial position, the dark area detector 180 is moved into the optical path connecting the variable magnification lens block 8 and the mirror 9. When the movement of the dark area detector 180 into the optical path is completed, the motor 33 is driven by the control of the first sub-processor 72 via the pulse motor driver 79, and the first carriage 4
11 is moved from the home position HP corresponding to the copying magnification to the scanning start position in the direction of the second carriage 412 (al>) (ST5).

Thereafter, the exposure lamp 4 is turned on under the control of the main processor group 71 via the lamp regulator 81, and the first carriage 411 is moved in the direction (a2) away from the second carriage 412.
(bright/dark discrimination) scanning is started (ST6), that is, the light reflected from the document G by the light irradiation of the exposure lamp 4 is reflected by the mirror 5°6.7, and then passes through the variable magnification lens block 8. The light is supplied to the dark area detector 180 and imaged onto the line sensor 131 by the at-lens 181 .

In this case, only the reflected light reflected by the document G is imaged on the line sensor 131, and the light irradiated around the document G is not reflected by the opening of the document cover 11 and is not imaged on the line sensor 131. As a result, the periphery of the original G becomes dark, which appears as an unnecessary black image in the copied image. Furthermore, when the preliminary scanning is completed, the exposure lamp 4 is turned off and the first carriage 411 starts scanning. It is returned to the position (a3).

Next, the erasing range is determined by detecting dark areas (non-reflective areas) other than the document image area based on the output of the line sensor 131 (ST7)', that is, the image information from the line sensor 131 is It is supplied to the image processing section 170 under the control of the main processor group 71. In this image processing unit 170, a black area (dark area) on the image information is identified, and based on the result of this identification, an erasure range (
The data indicating the non-image area) is stored in the bitmap memory 140.
stored within.

Once the erasing range is determined in this way, the motor 135 is driven in the opposite direction, and the dark area detector 180 is moved out of the optical path (ST8).

Then, when the movement of the dark area detector 180 out of the optical path is completed, an image forming operation accompanied by an erasing operation is started (ST9). That is, the exposure lamp 4 is turned on, and the motor 33 is driven to By moving the carriage 411 from the scanning start position in the direction (a4) away from the second carriage 412, scanning for image formation (main scanning) is performed. Further, under the control of the second sub-processor group 73 via the pulse motor driver 80, the motor 36 is driven to operate the photosensitive drum 10, and the array drive section 160 drives the erasing array 150.
As described above, the lighting of the light emitting element 152 is controlled according to the data from the bitmap memory 140. This corresponds to the non-image area where the light emitting element 152 is turned on.
The surface charge on the photoreceptor drum IO charged by the charger 11 is removed. Among the charged parts of the photosensitive drum 10, the part whose charge has been removed by the erasing array 150 does not form an electrostatic latent image even if it is exposed to light. If the paper size is smaller than the specified paper size, or even if the size of the original G and the paper size are equal, the copy size according to the copy magnification by the magnification setting key 30h may be smaller than the paper size, or the original G may be skewed and not correct. 18(b), the copied image formed on the paper P has an unnecessary black frame around the original image (a black frame shown with diagonal lines in FIG. 18(a)). ) will not appear, and you can always obtain beautiful copied images as copies.

In addition, even when the document cover 11 does not completely contact the document table 2 due to not only a sheet-like document G but also a thick document such as a book, the periphery of the document image may be removed as shown in FIG. 19(b). It is possible to erase the unnecessary black image @ (the black frame indicated by diagonal lines in FIG. 19(a)) that appears in the image, and it is possible to obtain a beautiful copy image. In the above embodiment, as shown in FIG. 18(b) and FIG. 19(b), the document image, including a part of it, indicated by the broken line in the figure is erased (erased) due to the diffusion of the irradiated light by the light emitting element 152. (The range is indicated by a two-dot H line), so that unnecessary black images appearing around the original image can be completely erased from the copied image.

On the other hand, if it is determined that the erase mode is not specified in step 2, or if the document cover 11 is not opened in step 3, that is, if the document cover 11 and the document table 2 are in complete contact with each other, If it is determined, the process moves to step 10, and a normal copying operation is performed. In this case, the first carriage 411 is moved from the home position HP corresponding to the magnification in the direction (al) of the second carriage 412, and its f&exposure lamp 4 is turned on to move away from the second carriage 412 (al).
a2), thereby performing scanning for image formation. When scanning of the original is completed, the exposure lamp 4 is turned off and the first carriage 411 is returned to the home position WHP.

As mentioned above, by detecting dark areas (non-reflective areas) from the light reflected from the document surface by scanning the optical system and removing the charge on the corresponding photoreceptor drum, images appearing in areas other than the original image can be removed. I'm trying to delete it.

In other words, a line sensor receives reflected light from the document surface due to light irradiation from an exposure lamp, and the output of this line sensor is used to identify black areas on the image information, thereby detecting areas where the document does not exist as dark areas. In addition, the surface charge of the photosensitive drum corresponding to the outer side of the peripheral edge of the document is removed. As a result, even if the document cover is not closed or cannot be closed, an electrostatic latent image is not formed on the photoreceptor drum outside the document image area, so that the No toner is deposited by development, so
Even if the original size is smaller than the paper size, the copy size is smaller than the paper size, or the original is not placed correctly, it is possible to prevent wasteful consumption of developer in areas other than the original image, and it also improves the appearance. It is possible to obtain beautiful, high-quality copied images.

In addition, it is possible to obtain beautiful copied images without unnecessary black images even when the document cover is left open, so it is expected to have effects such as eliminating the need to close the document cover every time a copy is made. .

Note that the present invention is not limited to the above embodiment. For example, the first carriage 411 is first moved in the direction of the second carriage 412 (the direction indicated by al in FIG. 1),
Preliminary scanning for bright/dark discrimination is performed by moving from the scanning start position (a2), but the second carriage 41
Preliminary scanning may be performed during movement in two directions (al). In this case, by performing main scanning for image formation during movement from the scanning start position (a2), one of the first carriages 411 Since the preliminary scan and the main scan can be performed by the reciprocating movement, it is possible to eliminate the unnecessary movement of the first carriage 411 for one extra reciprocating movement.

Furthermore, the arrangement position of the erasing array 150 is not limited to the position shown in FIG. 12, but as shown in FIG. It is also possible to configure erasing according to the erasing range.

Further, the dark area detector 180 may be moved by a drive mechanism as shown in FIG. 21.

That is, the atlens 181 and the line sensor 131
A dark area detector 180 consisting of is installed in a support 190,
This support body 190 is configured to be rotatable in the direction of the arrow shown in the figure using a shaft 191 as a fulcrum.

In this case, the dark area detector 180 is moved out of the optical path by, for example, driving the solenoid 192 and pulling down the arm 193 via the coil spring 194.
By stopping the driving of the solenoid 192, the dark area detector 180 is moved by the coil spring 195 in the direction of returning to the optical path. Furthermore, support 1
90 is fixed to a shaft 191, and the shaft 191 is rotationally controlled using a motor or the like.
The position of the dark area detector 180 may be moved, or the dark area detector 180 may be moved vertically with respect to the optical path.

In addition, the dark area detector 180 is moved into the optical path to form an image of the reflected light passing through the variable magnification lens block 8 on the line sensor 131. For example, as shown in FIG. The detector 180 may be placed outside the optical path so that light that does not pass through the lens block 8 is imaged on the sensor 131. In this case, a mechanism for moving the dark area detector 180 is not required. It is possible to have an extremely simple configuration.

Further, the arrangement position of the cover detection switch 600 is not limited to the position shown in FIG. 2, but as shown in FIG.
It is also possible to arrange it at the proximal end of 1. Further, the cover detection switch 600 is not limited to a combination of a magnet and a reed switch, but may also be an actuator 601 that is turned on/off in response to opening/closing of the document cover 1, for example.
and a microswitch 602.

Further, although the mode of "erase" is specified by operating the edit key 30g and the operation key 304, it is also possible to provide a dedicated key for mode specification on the operation panel 30.

Further, although the bitmap memory 140 is used in which sent data is stored in order, a memory in which data is stored in accordance with address specification may also be used.
Alternatively, it is also possible to use a memory with a small capacity by providing a compression/expansion circuit to store band-compressed data.

It goes without saying that various other modifications can be made without departing from the gist of the invention.

[Effects of the Invention] As detailed above, according to the present invention, even if the image forming operation is performed with the document cover not completely closed, the image will appear in areas other than the document image. It is possible to provide an image forming apparatus that can erase unnecessary black images, improve the quality of copied images, and prevent wasteful consumption of developer.

[Brief explanation of the drawing]

The drawings show one embodiment of the present invention, and FIG. 1 is a side sectional view without showing the structure of the copying machine, and FIG. 2 is a side view of the outside of the copying machine. l
3 is a plan view showing the configuration of the operation panel, FIG. 4 is a perspective view showing the configuration of the drive section, FIG. 5 is a perspective view schematically showing the drive R structure of the optical system, and FIG. The figure is a perspective view schematically showing the drive mechanism of the pointer, FIG. 7 is a block diagram showing the overall control circuit, FIG. 8 is a perspective view schematically showing the drive mechanism of the dark area detector, and FIG. 10 is a side sectional view of the main part showing the arrangement of the dark area detector, FIG. 10 is a diagram shown to explain the detection operation using the dark area detector, FIG. 11 is a diagram shown to explain the contents of the memory, and FIG. FIG. 12 is a side sectional view of the main parts showing the arrangement of the erasing array, FIGS. 13 and 14 respectively show the relationship between the erasing array and the photosensitive drum, and FIG. 13 is a perspective view showing only the main parts. 14 is a front view showing only the main parts, and FIG. 15 shows the configuration of the erasing array.
Figure (a) is a side sectional view, Figure (b) is a partially cutaway front view, Figure 16 is a circuit diagram showing the configuration of the array drive section, and Figure 17 explains the operation. FIG. 18 is a flowchart for explaining the operation by comparing the embodiment and the conventional example using a sheet-like original as an example, and FIG. Fig. 19 is an explanatory diagram of a conventional example showing a case where an unnecessary black image appears. Fig. 19 is an explanatory diagram of an embodiment showing a case where an unnecessary black image is erased from a copied image. The figures are shown to compare and explain the embodiment and the conventional example, and FIG.
) is an explanatory diagram of an embodiment showing a case where an unnecessary black image is erased from a copied image, FIG. 20 is a side cross-sectional view of the main part showing another example of the arrangement of the erasing array, and FIG. 21 is a diagram showing the dark area detector. FIG. 22 is a perspective view schematically showing another configuration example of the moving drive mechanism; FIG.
FIG. 3 is a diagram showing another embodiment of the cover detection switch. 1...Main body, 2...Original table, 4...Exposure lamp,
8... Lens block for variable magnification, 10... Photoconductor drum (photoconductor), 30... Operation panel, 411... 1st-'r ridge, 71... Main processor group, 1
31... Line sensor, 135... Pulse motor,
140...Bitmap memory, 150...Erasing array, 160...Array drive section, 170...Image processing section, 180...Dark area detector, 181...Atlens, 600...Cover Detection switch. Applicant's agent Takehiko Suzue ) Figure 19 Figure 20 Figure 21 Figure 22 Figure 23

Claims (1)

[Claims] A document placed on a document table is optically scanned by an optical system to form an image corresponding to the image of the document on a charged photoreceptor, and this image is developed to cover the image. In an image forming apparatus for transferring onto a transfer material, a detection means for detecting a dark part from light reflected from a document surface by scanning by the optical system, and a charge on the photoreceptor corresponding to the dark part detected by the detection means is removed. An image forming apparatus comprising: a removing means for removing an image.