Image forming apparatus

A carriage acting as a light shielding plate is moved along a table in accordance with a desired copying magnification and binding margin which is displayed between a stationary scale and a movable scale provided on the carriage. A display is provided on the carriage for selectively displaying the preset copying magnification and the desired binding margin in response to a position of the carriage.

BACKGROUND OF THE INVENTION 
The present invention relates to an image forming apparatus which displays 
an image formation range when an image is formed. 
Recently, an image forming apparatus, e.g., an electronic copying machine 
having functions for copying an image of an original on a paper sheet 
without changing its size, enlarging or reducing copy, or forming an image 
with a noncopied section to be utilized as a binding margin or the like 
has been developed. However, in such a copying machine, a preset copying 
magnification or an image forming range is only quantitatively displayed 
on a control panel, and an operator cannot grasp the relationship of the 
copy to be made relative to the original. 
SUMMARY OF THE INVENTION 
It is an object of the present invention to provide an image forming 
apparatus, of good operability, which can directly and quantitatively 
display the copying range and the non-copying range on an image of the 
original. 
According to the present invention, there is provided an image forming 
apparatus which displays an image forming range and an image nonforming 
range by using first and second carriages and an image of an original, as 
an optical scanning means.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT 
An image forming apparatus according to an embodiment of the present 
invention will be described with reference to the accompanying drawings. 
FIGS. 1 and 2 are schematics of an image forming apparatus such as a 
copying machine. An original table (a transparent glass) 2 for supporting 
an original is fixed on the upper surface of a housing 1. A stationary 
scale 2.sub.1 is disposed in the table 2 and serves as a fixed reference. 
An openable original cover 1.sub.1 and a work table 1.sub.2 are arranged 
near the table 2. The original placed on the table 2 can be scanned while 
an optical system consisting of an exposure lamp 4 and mirrors 5, 6 and 7 
reciprocates back and forth in the direction indicated by arrow a. In this 
case, the mirrors 6 and 7 are moved at a speed half that of the mirror 5 
so as to ensure the proper optical length. Light reflected by the original 
upon scanning by the optical system, that is, light reflected by the 
original upon illumination from the lamp 4, is reflected by the mirrors 5, 
6 and 7 and passes through a magnification change lens block 8. The light 
is then reflected by the mirror 9, and the reflected light is directed to 
a photosensitive drum 10. 
The image of the original is focused on the surface of the drum 10. The 
drum 10 is rotated in the direction indicated by arrow c and is charged by 
a charger 11. Thereafter, the image is exposed through a slit, so that a 
latent image is formed on the surface of the drum 10. The latent image is 
rendered visible by the developing unit 12 upon application of toner to 
the latent image. 
Sheets (transfer media) P are fed from a selected upper or lower paper 
cassette 13 or 14 by a pickup roller 15 or 16, one by one. The fed sheet 
is guided to an aligning roller pair 19 through a paper guide path 17 or 
18. The sheet is then fed by the rollers 19 to the transfer section. The 
cassettes 13 and 14 are detachably attached to a portion of the lower end 
of the right side of the housing 1. An operator selects one of the 
cassettes at a control panel to be described later. The sizes of the 
cassettes 13 and 14 are detected by cassette size sensor switches 60.sub.1 
and 60.sub.2. The switches 60.sub.1 and 60.sub.2 comprise a plurality of 
microswitches which are turned on/off upon attachment/detachment of the 
corresponding cassettes. 
The sheet P fed to the transfer section is brought into close contact with 
the surface of the drum 10, and a toner image is transferred by the 
charger 20 from the surface of the drum 10 to the sheet P. The 
image-transfer sheet P is electrostatically separated from the drum 10 by 
a separating charger 21, and the sheet is fed to the fixing roller 23 
which serves as a fixing unit arranged at the terminal end of the conveyor 
belt 22. The transfer image is fixed while the sheet passes by the fixing 
roller 23. The sheet P is finally discharged by a discharge roller pair 24 
outside the housing 1 and is placed on the tray 25. After the transfer 
operation, the drum 10 is discharged by the discharger 26, and residual 
toner left on its surface is removed by a cleaner 27. The surface of the 
drum 10 is finally quenched by a lamp 28 so that the drum 10 is restored 
to is original state. Reference numeral 29 denotes a cooling fan for 
preventing a rise in temperature. 
FIG. 3 shows a control panel 30 arranged on the housing 1. Reference 
numeral 30.sub.1 denotes a copying key for designating start of copying; 
30.sub.2, a ten-key pad for entering a copying number; 30.sub.3, a display 
for displaying operating states of the respective components (paper jam 
and the like); 30.sub.4, a cassette selection key for selecting one of the 
cassettes 13 and 14; 30.sub.5, a cassette display for displaying the 
selected cassette; 30.sub.6, a magnification setting key for setting an 
enlargement or reduction coefficient of an image at a predetermined rate; 
30.sub.7, a zoom key for setting an enlargement or reduction coefficient 
of the image in a nonstep manner; 30.sub.8, a display for displaying the 
set enlargement or reduction coefficient; 30.sub.9, a density setting 
section for setting the copying density; 30a and 30b, operation keys for 
setting the width of an image nonforming range or binding margin (to be 
described later) of an original; and 30c, a display for displaying the 
preset width of the binding margin. 
FIG. 4 shows the arrangement of drive sources of the respective drive 
mechanisms in the copying machine arranged as described above. The drive 
sources are given as follows: reference numeral 31 denotes a lens motor 
for shifting the position of the block 8 so as to form an enlarged or 
reduced image; 32, a mirror motor for changing the optical length such 
that it corresponds to the distance between the mirror 5 and the mirrors 6 
and 7; 33, an original scanning mirror for moving the mirrors 5, 6 and 7 
so as to scan the original; 34, a shutter motor for moving a shutter (not 
shown) to adjust the charge width of the charger 11 for the drum 10 in the 
magnification change mode; 35, a developing motor for driving the 
developing roller 12; 36, a drum motor for driving the drum 10; 37, a 
fixing motor for driving the path of the conveyor belt 22 and the pair of 
fixing roller 23 and discharge roller 24; 38, a paper feed motor for 
driving the rollers 15 and 16; 39, a paper feed motor for driving the 
roller pair 19; and 40, a fan motor for driving the fan 29. 
FIG. 5 shows the optical system drive mechanism. The mirror 5 and the lamp 
4 are supported on the first carriage 41.sub.1, and the mirrors 6 and 7 
are supported on the second carriage 41.sub.2. The carriages 41.sub.1 and 
41.sub.2 are guided along guide rails 42.sub.1 and 42.sub.2 and are moved 
parallel to each other in the direction indicated by arrow a. The 4-phase 
motor 33 drives a pulley 43. An endless belt 45 is looped between the 
pulley 43 and an idler pulley 44. One end of the mirrors 5 supporting 
carriage 41.sub.1 is fixed midway along the belt 45. Two pulleys 47 are 
rotatably provided in a guide portion 46 in the carriage 41.sub.2 for 
supporting the mirrors 6 and 7 and are spaced apart along the axial 
direction of the rail 42.sub.2. A wire 48 is looped between the pulleys 
47. One end of the wire 48 is fixed to a stationary portion 49, and the 
other end thereof is fixed to the portion 49 through a coil spring 50. One 
end of the carriage 41.sub.1 is fixed midway along the wire 48. When the 
motor 33 is rotated, the belt 45 is rotated accordingly and the carriage 
41.sub.1 and then the carriage 41.sub.2 are moved. In this case, the 
pulleys 47 serve as movable rollers so that the carriage 41.sub.2 is moved 
at a speed half that of the carriage 41.sub.1, but in the same direction. 
The direction of the carriages 41.sub.1 and 41.sub.2 movement is 
controlled by changing the rotational direction of the motor 33. 
A possible copying range corresponding to the specified sheet size is 
displayed in the table 2. Assume that a paper size designated by the key 
30.sub.4 is given as (Px,Py) and a copying magnification coefficient 
designated by the keys 30.sub.6 and 30.sub.7 is given as K. A possible 
copying range (x,y) is defined as "x=Px/K" and "y=Py/K". An x-axis length 
of the range (x,y) is displayed as a mutual distance between indexes 51 
and 52 arranged on the lower surface of the table 2, and a y-axis length 
is displayed on a scale 53 arranged on the upper surface of the carriage 
41.sub.1. 
The indexes 51 and 52 are arranged on a wire 57 looped around pulleys 54 
and 55 through a spring 56, as shown in FIG. 6. The pulley 55 is rotated 
by the motor 58. When the motor 58 is driven to achieve copying in the x 
direction, the distance between the indexes 51 and 52 can be changed. 
The carriage 41.sub.1 is driven by the motor 33 to a predetermined position 
(i.e., a home position based on each magnification coefficient) in 
accordance with the paper size and the magnification coefficient. When the 
key 30.sub.1 is depressed, the carriage 41.sub.1 is moved toward the 
carriage 41.sub.2. Thereafter, the lamp 4 is turned on and the carriage 
41.sub.1 is moved away from the carriage 41.sub.2. When original scanning 
is completed, the lamp 4 is turned off, and the carriage 41.sub.1 returns 
to the home position. 
FIG. 7 shows the overall arrangement of a control circuit. A main processor 
group 71 receives output from the panel 30 and the switches and sensors 
(switches/sensors 75 such as the switches 60.sub.1 and 60.sub.2), and 
controls a high voltage transformer 76 for driving the various chargers 
described above: the discarge lamp 28, a blade solenoid 27a of the cleaner 
27, a heater 23a of the pair 23, the lamp 4 and the motors 31 to 40 and 
58, thereby performing copying. At the same time, the group 71 also 
controls a spotlight source 84, a pulse motor 95, a memory 120, an erasure 
array 100 and an array drive mechanism 110 so as to erase the unwanted 
portion of the original. The source 84, the motor 95, the array 100, the 
array drive mechanism 110 and the memory 120 will be described later. 
The motors 35, 37 and 40, among the motors 31 to 40 and 58, and a toner 
motor 77 for supplying toner to the unit 12 are controlled by the group 71 
through a motor driver 78. The motors 31 to 34 and 95 are controlled by a 
first sub-processor group 72 through a pulse motor driver 79. The motors 
36, 38, 39 and 58 are controlled by a second sub-processor group 73 
through a pulse motor driver 80. The lamp 4 is controlled by the group 71 
through a lamp regulator 81, and the heater 23a is controlled by the group 
71 through a heater control section 82. The group 71 supplies to the 
groups 72 and 73 control signals for designating driving/interruption of 
the motors. The groups 72 and 73 supply to the group 71 status signals 
representing the driving/interruption states of the motors. The group 71 
receives position data from a position sensor 83. The position data 
represent the initial positions of the motors 31 to 34. 
FIG. 8 shows an arrangement of the group 71. A one-chip microcomputer 91 
detects key input at the control panel (not shown) and performs various 
display control operations through an I/O port 92. The microcomputer 91 
can be expanded through I/O ports 93 to 96. The port 93 is connected to 
the transformer 76, the driver 78, the regulator 81 and other outputs. The 
port 94 is connected to the size switch for detecting paper size and other 
input. The port 95 is connected to the copying condition preset switch and 
other input. The port 96 serves as an optional port. 
FIG. 9 shows an arrangement of the group 72. A microcomputer 101 is 
connected to the group 71. A programable interval timer 102 controls the 
switching interval of the pulse motor. A value is preset from the 
microcomputer 101 to the timer 102, and the timer starts counting the 
reference clock pulses. When the timer 102 count is completed, the timer 
102 sends an end pulse onto an interrupt line of the microcomputer 101. 
The microcomputer 101 receives position data from the sensor 83 and is 
connected to I/O ports 103 and 104. The port 104 is connected to the 
motors 31 to 34 and 95 through the driver 79. The port 103 is used for 
supplying the status signals of the pulse motors to the group 71. 
FIG. 10 shows an arrangement of the group 73. A microcomputer 111 is 
connected to the group 71. A programable interval timer 112 controls the 
switching interval of the pulse motor. When a value is preset from the 
microcomputer 111 to the timer 112, the timer 112 starts counting the 
reference clock pulses. When the timer 112 completes its count, an end 
pulse therefrom is latched by a latch 113. An output from the latch 113 is 
supplied to the interrupt line of the microcomputer 111 and the I/O port 
input line. The microcomputer 111 is also connected to an I/O port 114. 
The port 114 is connected to the motors 36, 38, 39 and 58 through the 
driver 80. 
FIG. 11 shows a pulse motor control circuit. An I/O port 121 (corresponding 
to the ports 104 and 114 of FIGS. 9 and 10) is connected to a pulse motor 
driver 122 (corresponding to the drivers 79 and 80 of FIG. 7). The driver 
122 is connected to windings A, B, A and B of a pulse motor 123 
(corresponding to the pulse motors 31 to 34, 36, 38 and 39). 
FIGS. 12(a) and 12(b) show a method of controlling the speed of the pulse 
motor. FIG. 12(a) shows the speed curve of the pulse motor, and FIG. 12(b) 
shows phase switching intervals. As is apparent from FIGS. 12(a) and 
12(b), the switching intervals are long at the beginning, are gradually 
decreased, and are then finally equalized. Then, the intervals are 
prolonged, and the pulse motor is stopped. This sequence indicates the 
cycle-up and cycle-down of the pulse motor. The motor is started from the 
self-starting region, operated in a high-speed region and is gradually 
stopped. Reference symbols t1, t2, . . . tx denote times between the 
switching intervals. 
FIGS. 13A and 13B are flow charts explaining the operation of the one-chip 
microcomputer 91 in the main processor group 71. 
In step 1, the microcomputer 91 fetches output from the control panel, the 
switches and the sensors. 
In step 2, the first carriage indicating a preset image forming range is 
moved vertically so as to display an image nonforming range. 
In step 3, the image nonforming range set in step 2 is calculated and 
displayed on the display unit of the control panel. 
In step 4, it is checked if the copy start key is depressed. 
In step 5, timing of the exposure lamp (paper feed) is controlled in 
accordance with the image forming and nonforming ranges so as to scan the 
original under the copying conditions set in step 1 and thereby form a 
latent image on the photosensitive drum. 
In step 6, toner is attached to the latent image on the drum to form a 
toner image. 
In step 7, the toner image on the drum is transferred to the sheet. 
In step 8, the drum is discharged to remove residual toner. 
An arrangement for displaying the image forming range of an original as a 
main feature of the present invention will be explained with reference to 
FIGS. 14 to 21. In this apparatus, the first carriage 41.sub.1 and the 
indexes 51 and 52 are driven in accordance with the preset magnification 
so to display the image forming range, and the first carriage 41.sub.1 is 
driven so as to display the image nonforming range utilized as, e.g., a 
binding margin at the left or right of the copied image. The position and 
width of the image nonforming range (to be referred to as a binding margin 
hereinafter) can be set by operating the operation key 30a or 30b. The 
preset width is displayed on both the display 30c and the table 2 by the 
movable scale 53 provided on the carriage 41.sub.1 and the stationary 
scale 2.sub.1 provided on the left side frame of the table 2. As indicated 
by the solid line in FIG. 14, the carriage 41.sub.1 is normally set in a 
standby state at a position corresponding to a preset copy enable range. 
In this state, when the key 30a is depressed the motor 33 is driven and 
the carriage 41.sub.1 is moved in the direction of the scale 2.sub.1. As 
indicated by the alternate long and a short dashed line in FIG. 14, when 
the carriage 41.sub.1 is located adjacent to the scale 2.sub.1, the keys 
30a and 30b are appropriately operated, thereby setting the width .delta. 
of the desired binding margin. The width .delta. is defined by the mutual 
distance between the scales 2.sub.1 and 53. Therefore, an operator can 
confirm the binding margin on the table 2 in accordance with the state in 
which the original G is set thereon. Since the display 30c of the panel 30 
quantitatively displays the width of the binding margin, the width can be 
quantitatively set with reference to the display 30c. 
Display operation of the display 30c is performed, e.g., in such a manner 
that drive pulses of the motor 33 are counted so as to obtain the distance 
the carriage 41.sub.1 moves, with the width being calculated from the 
movement distance. Note that "+" and "-" indicate the forming position of 
the binding margin. When "+" is displayed, the binding margin is formed at 
the left of the copied image, and when "-" is displayed, at the right 
thereof. However, when the setting direction of the original is vertically 
reversed, the forming position of the binding margin is also reversed. 
FIG. 14 shows the position of the scale 53 when "+" is displayed, and FIG. 
15 shows a position thereof when "-" is displayed. A boundary of "+" and 
"-" corresponds to an edge of the scale 2.sub.1. 
As shown in FIGS. 14 to 16, an m.times.n opening 2.sub.2 is provided at one 
end of the scale 2.sub.1 so that the transparent glass of the table 2 is 
partially exposed therethrough. Therefore, when the binding margin is set 
in the "-" direction, or when the binding margin is set to be .delta.=0 
mm, the scale 53 can be visually observed through the opening 2.sub.2, and 
the width of the binding margin can be easily checked. 
When the key 30.sub.1 is depressed after the width of the binding margin is 
set, an exposure timing of the lamp 4 or a paper feed timing of the sheet 
P is controlled in a known manner, and a binding margin P.sub.1 is formed 
together with a desired image, as shown in FIG. 17. 
As shown in FIGS. 14 to 16, a display 130 is formed in a portion of a 
surface of a light shielding plate 41a of the carriage 41.sub.1 to be 
adjacent to the scale 53 and at a position substantially parallel to the 
opening 2.sub.2. The display 130 can selectively display a copying 
magnification and the binding margin, as shown in FIG. 18. FIG. 18 shows a 
state wherein all the segments of the display 130 are turned on, in which 
reference numeral 131 denotes a display indicating a copying magnification 
display; 132, a display indicating a binding margin display; 133, a 
display indicating the forming position of the binding margin; 134, a 
display indicating the copying magnification; 135 and 136, displays 
indicating units of the copying magnification and the binding margin. 
A display signal supplied to the display 130 is the same as that supplied 
to the displays 30.sub.8 and 30.sub.C of the control panel. The signal 
supplied to the display 134 indicating the preset value of the copying 
magnification or the binding margin and the display 133 indicating the 
forming position of the binding margin are the same as those supplied to 
the displays 30.sub.8 and 30.sub.C. The main processor group 71 
selectively supplies a signal for driving the display 131 indicating the 
copying magnification, the display 132 indicating the binding margin and 
the displays 135 and 136 for displaying the preset values of the copying 
magnification and the binding margin. 
With this structure, since the first carriage 41.sub.1 is normally set in 
the standby state at a position indicating an image forming range 
corresponding to the copying magnification, the display 10 displays the 
copying magnification, as shown in FIG. 19. When the binding margin 
display mode is set in this state, a width of the binding margin 
corresponding to the preset value is displayed, as shown in FIG. 20. In 
this manner, the image forming range corresponding to the copying 
magnification and the image nonforming range used as the binding margin 
can be displayed in accordance with the position at which the first 
carriage 41.sub.1 is stopped. Therefore, since the image forming and 
nonforming ranges can be visually observed with reference to the original 
on the table 2, these ranges can be easily checked. 
Since the image forming and nonforming ranges are displayed by utilizing 
the first carriage 41.sub.1, a special arrangement is not required, and an 
increase in the number of components is not necessary. Also since the 
image forming and nonforming ranges are quantitatively displayed on the 
display 130 which is provided on the first carriage 41.sub.1, an operator 
can check the preset value without checking the control panel 30 when he 
sets the original on the table 2, thereby resulting in excellent 
operability. 
Note that the display 130 need not be provided on the light shielding plate 
41a of the first carriage 41.sub.1, for it can be provided on the outer 
side surface of the first carriage 41.sub.1, as shown in FIG. 21. With 
this structure, the display 130 can be shielded from heat from the 
exposure lamp 4, and degradation in display 130 can be prevented. For the 
display 130, a liquid crystal panel or a light emitting diode having a 
segment structure can be used. 
Furthermore, in the above embodiment, the image forming and nonforming 
ranges are displayed by the positions of the first carriage 41.sub.1 
stationary scale 2.sub.1 and the indexes 51, 52. However, the image 
forming range can be displayed by the positions of the first carriage 
41.sub.1 and the indexes 51, 52, and the second carriage 41.sub.2 can be 
independently driven so as to display the image nonforming range which is 
formed at the right or left of the image and utilized as the binding 
margin. In this case, a forming position and the width of the binding 
margin are set upon depression of the keys 30a and 30b of the control 
panel 30. The preset width is displayed on the display 30c and a movable 
scale 59 provided on the second carriage 41.sub.2 relative to the 
stationary scale 2.sub.1 provided on the table 2, as shown in FIGS. 22 and 
23. 
Therefore, as indicated by the dotted line in FIG. 22, when no binding 
margin is formed, i.e., when the preset value of the binding margin is 0 
mm, the second carriage 41.sub.2 is set in the standby state at a position 
at which the scale 59 coincides with the edge of the scale 2.sub.1. In 
this state, when the keys 30a and 30b are properly operated, the second 
carriage 41.sub.2 is moved by a pulse motor 33.sub.2 in the direction 
indicated by an arrow in FIG. 22. FIGS. 24 26 show this state and indicate 
that the width .delta. of the binding margin is represented by the scales 
2.sub.1 and 59. 
Therefore, an operator can check the binding margin on the table 2 while 
setting the original G thereon. The width also can be quantitatively set 
with reference to the display 30c of the panel 30. Since the distance the 
second carriage 41.sub.2 moves is obtained by counting drive pulses of the 
pulse motor 33.sub.2, the width is calculated from the count so as to be 
displayed. "+" or "-" on the display 30c indicates the forming position of 
the binding margin. As shown in FIG. 24, when "+" is displayed, the 
binding margin is formed at the left of the image, and when "-" is 
displayed, it is formed at the right of the image. Note that when the 
setting position of the original is reversed, the forming position of the 
binding margin is also reversed. 
As shown in FIGS. 22, 24 and 25, the m.times.n opening 2.sub.2 is provided 
so as to expose a transparent glass therethrough. Therefore, when the 
binding margin is set in the "-" direction or when the binding margin is 
set to be .delta.=0 mm, the movable scale 53, 59 can be visually observed 
through the opening 2.sub.2, and the width of the binding margin can be 
easily checked. 
When the copy key 30.sub.1 is depressed after setting the width of the 
binding margin, the second carriage 41.sub.2 is moved to the left of the 
stationary scale 2.sub.1, and the first carriage 41.sub.2 is moved in the 
direction toward the stationary scale 2.sub.1. Thereafter, the second 
carriage 41.sub.2 follows the first carriage 41.sub.1 at a speed 1/2 that 
of the first carriage 41.sub.1. Then, as described above, the exposure 
timing of the lamp 4 or the paper feed timing of the sheet P is controlled 
based upon the preset value in a known manner, and, as shown in FIG. 27, 
the binding margin P.sub.1 is formed on the sheet P together with the 
desired image. Note that FIG. 27 shows the state where the binding margin 
is set in the "+" direction, as shown in FIG. 24. 
The first and second carriages 41.sub.1, 41.sub.2 are independently driven, 
and the image forming range is indicated by the first carriage 41.sub.1, 
whereas the image nonforming range is indicated by the second carriage 
41.sub.2. Therefore, these ranges can be easily checked on the table 2. 
Since the image forming and nonforming ranges are indicated by using the 
scale 53, 59 provided on the first and second carriages 41.sub.1, 
41.sub.2, a special mechanism is not required, and only a slight increase 
in the number of components is necessary. In the above embodiment, the 
indexes 51 and 52 are provided on the second carriage 41.sub.2, but the 
present invention is not limited to this. They can be provided at, e.g., 
the rear side of the stationary scale 2.sub.1. 
When the copying magnification is to be changed, e.g., when a B4-size 
original G is to be copied to an A4-size paper P in an enlargement mode, 
the copying magnification is 116% (K=1.16). In this case, although the 
width .delta..sub.P of the binding margin is displayed after the copying 
operation, the scale 59 provided on the second carriage 41.sub.2 is set at 
a position .delta..sub.K =.delta..sub.P /K as shown in FIG. 28. Then, 
since y.sub.KO =y.sub.P /K with respect to the width y.sub.P of the paper 
P, the scale 53 of the first carriage 41.sub.1 is set at a position of 
y.sub.K =y.sub.KO +.delta..sub.K =(y.sub.P +.delta..sub.P)/K. That is, the 
region existing between the first and second carriages 41.sub.1, 41.sub.2 
represents the actual copying range. Since the first carriage 41.sub.1 
indicates a copying area in the y direction and the second carriage 
41.sub.2 indicates the binding margin, the copying area and the binding 
margin can be simultaneously displayed.