JPS63123736A - Display device for remaining amount of transfer sheet in copy machine - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

[Detailed description of the invention] (Technical field) The present invention relates to a transfer paper remaining amount display device for a copying machine.

(Prior Art) The copying speed of a general copying machine varies depending on the size of the transfer paper, and the larger the size, the slower the copying speed. However, since the remaining amount of transfer paper in conventional copying machines was displayed based on the amount of paper regardless of the size of the paper, there was a problem in that it was unclear how much time the copying machine could use.

(Purpose) The present invention was made based on this background,
The purpose is to improve the operability of the copying machine by displaying the usable time of the transfer paper.

(Structure) For this purpose, the present invention includes a remaining amount detection means for detecting the remaining amount of transfer paper for transferring an original image, and a remaining continuous usable time that is calculated from this data, original size data, and copying speed data. The present invention is characterized in that it includes a means and a display section thereof, and displays the remaining amount of transfer paper in terms of usable time.

Hereinafter, one embodiment of the present invention will be described based on the drawings.

FIG. 1 is a configuration diagram of a copying machine according to the present invention.
and a circulating document feeder (hereinafter referred to as RDF) B. The copying operation when using these will be explained.

The copying operation is started by setting the necessary copying format on the operation section provided on the copying machine main body A and pressing the start button. Here, a copying operation using RDF will be explained.

The RDF has a document tray 201, and the document placed there is fed by a document feed belt 202, passes through a document conveyance path 203, and is conveyed onto the contact glass 101. Thereupon, the entire surface of the document is irradiated with light by the flash lamp 102. The power source 103 of the flash lamp is charged in advance by a control device, which will be described later, and emits light at a predetermined timing.

The reflected light from the original passes through the first mirror 104, the through lens 105, and the second mirror 106 to expose the belt photoreceptor 107. The photoreceptor 107 is uniformly charged with a charge by a charger 108, and forms an electrostatic latent image by exposure.

The electrostatic latent image on the photoreceptor 107 has unnecessary charges removed by an eraser 109, is developed by a developer 110, and is sent to a transfer section. Then, the developed original image is transferred to a transfer paper by the transfer charger 111. The transfer paper is fed from one of paper feed trays 112, 113, and 114, passes through a conveyance path 115, and passes through a registration roller 116.
The image is sent through the transfer unit in synchronization with the original image.

The image-formed transfer paper is conveyed by a conveyor bell! -117, is fixed by the fixing device 11B, and is conveyed to the output tray 119.

The document on the contact glass 101 is transferred to the document conveyor belt 2.
04, the document is sent out after the light irradiation is completed, and returned to the document tray 201 by the document discharge roller 206. The document ejection roller 206 can rotate forward and backward, and if you want the front and back sides of the document to be the same as the original state, the trailing edge of the document will be rotated by the document switching claw 20.
5, the document discharge roller 206 is reversed and the document is discharged through the normal rotation conveyance path 207. If the document is desired to be reversed, the document discharge roller 206 is driven as it is and the document is discharged through the reverse conveyance path 208.

Since this belt photoreceptor has seams, the image forming areas on the belt are determined to be equally spaced for each size, avoiding the seams of the belt photoreceptor.

FIG. 2 is a diagram showing an example of the arrangement of image forming areas (segments) on a belt photoreceptor cut at a seam and developed. In the example in FIG. The four A3 segments shown by the two-dot M line are determined so that the three A3 segments are equally spaced from each other.

FIG. 3 is a control block diagram for forming an image on the belt photoreceptor, and is shown together with the belt photoreceptor 107.

This operation will be explained below.

As described above, in order to avoid seams during image formation, it is necessary to determine the image forming area on the photoreceptor prior to image formation. For this purpose, a synchronization mark 2 (Fig. 2) is provided on the edge of the belt photoreceptor at a certain distance from the seam l (Fig. 2), and the 0 image forming area is detected by the mark sensor 15. In order to determine this mark, it is necessary to drive the photoreceptor 107 and detect this mark. For this purpose, a drive signal from the output boat 13 is input to the motor control circuit 14, and the motor control circuit 14 controls the photoreceptor drive motor 15.
is driven. Encoder 16 to photoreceptor drive motor 5
are integrally attached and output a number of pulses proportional to the moving distance of the belt photoreceptor 107. The pulse signal is input to the motor control circuit 14 and used to rotate the photoreceptor drive motor 15 at a constant speed.

Further, the pulse is input to the frequency dividing circuit 12, and after being divided by a predetermined frequency division ratio, is input to the CPU10, and the pulse is input to the CPU10.
It is counted by l0. Since this signal is proportional to the amount of movement of the photoreceptor 107, the image forming area is determined by this count value.

- Determination of A4 segments will be specifically explained as an example.

The number of pulses per revolution of the photoreceptor 107 is set to no.

This means that the synchronization mark 2 on the photoreceptor 107 is the mark sensor 1.
7 and input as a mark signal to the input port 11 until the next mark signal is detected. The value obtained by dividing this pulse number n by 5, which is the number of A4 segments, becomes the width of the image area of the A4 segment. The pulse value at the beginning of the image area is given by the following equation.

Pulse value at the beginning of A4 segment = a+nX (no15
) n-0, 1, 2, 3, 4 Next, the latent image forming operation in the copying operation will be explained.

When the leading value of the segment reaches a predetermined value, a sequence operation starts, and a sequence control counter starts operating. This counter performs a count-up operation in response to a pulse signal from the frequency dividing circuit 12, but is not cleared by a mark signal and continues to perform a count-up operation until the sequence is completed. The operation will be sequentially explained below. When the counter starts operating and the count value reaches the value of CNTO, a signal is output from the output port 13 to the power back 18, and the transfer charger 111 and the separation charger 12
0 starts the operation. When the photoreceptor 107 further rotates and the count value reaches the CNTl0 value, the charger 108 operates in the same manner as described above, and the photoreceptor 107 is uniformly charged. When the count progresses further and the count value reaches CNT2, the flash power supply 103 is activated by the output port 13.
Charging start No. 42 is input to , and in order to light up the flash lamp, charge is stored in the capacitor in the flash power supply 103 and the flash signal is sent to the flash power supply 10.
3, the flash lamp 102 lights up,
The original set on the contact glass 101 is irradiated with light, and the reflected light is sent to the first mirror 104 and the through lens 10.
5. Expose the photoreceptor through the second mirror 106. The flash signal at this time is output when the count value is CNT3. Furthermore, this exposed image area is erased by the eraser 1.
09 removes charges from unnecessary portions and forms a latent image.

Next, FIG. 4 shows the operation and display section of the copying machine according to the present invention, and the operation mechanism will be explained.

Operation keys are 10 keys (1 to 9.0) 19, interrupt key 20
, clear/stop key 21, print key 22, density adjustment key 23, standard mode setting key 24, paper feed selection key 25, magnification setting key 26, screen original 1, double-sided copy key 27 for single-sided original, stack key 28 , sort key 2
9, RDF key 30, ADF key 31, display section 3
2.33 cannot normally be seen, but when it is turned on, a display like the one shown in the figure appears. Its functions will be explained below.

RDF and ADF keys 30 and 31 are circulation type document feeder B
The RDF is used to circulate the original and make a set number of copies, and the ADF is used to stop the original and make a set number of copies. The stack key 28 and the sort key 29 are well known and need no explanation.The double-sided copy key 27 is used when you want to make double-sided copies, and when you want to make double-sided copies from a double-sided original.
Sometimes a one-sided original is copied to two-sided. The paper feed selection key 25 is used to select paper feed trays 112, 113, and 114, and the display section 32 shows that the first paper feed tray has A4, and the second and third paper feed trays have B4. When A3 is set and the first row is selected, the A4 display area is surrounded by a frame. The display to the left is the remaining amount display, which will be explained in detail later.

To set the magnification, there is an enlargement key and a reduction key (magnification setting key 26), and when you press them, for example 1%
The percentage is displayed on the display section 49 in increments. And for example 171
When %' is displayed, "A3→A4" is also displayed, indicating that the magnification is to reduce A3 to A4.1
The 0 key 19 is used to set the number of sheets or copies, and is displayed in the upper seven segments of the display section 32. The lower 7-segment display is for displaying the number of copies. The interrupt key 20 is used when an emergency copy is required during copying. Pressing it will interrupt the copying, and pressing it again after performing the emergency copy will return to the previous mode and continue the copying. Can be restarted. The explanation of the clear/stop key 21, density adjustment key 23, and print key 22 will be omitted.

The standard mode setting key 24 is used to change to a preset mode by pressing it, and it is possible to cancel the previous copy format and call up the set mode.

This concludes the explanation of the keys. Next, the display functions of the display sections 32 and 33 that have not been explained yet will be explained.

A display 3201 is lit when the original and the transfer paper do not match, and the determination is made including the magnification.

Display 3202 is 0, which lights up when there is no paper in the paper feed tray.
Display 3203 lights up when copying the back side during double-sided copying.0 Display 3204 lights up when the sort or stack key is pressed when there is transfer paper in the sorter bin.
This is a warning not to mix it with previously copied transfer paper.

Display 3205 is a display warning that you have forgotten the original, and display 320
6 is a 0 display 330 that lights up when the interrupt key 20 is pressed.
1 is displayed as a number when there is an abnormality in the machine, and at this time the display 3302 also lights up, indicating a serviceman call. This number allows you to identify abnormalities and serves as a means of self-diagnosis.

Display 3303 lights up when the door is open.

Display 3304 lights up when a jam occurs.

Display 3305 lights up when the key counter is not set.

Display 3306 lights up when toner is insufficient.

FIG. 5 is a block diagram of the paper feed tray according to the present invention, and its operation will be explained.

This figure shows the paper feed tray 112 viewed from behind. When the transfer paper 34 is placed on the tray 35 and this paper feed tray is set, the paper feed tray motor 36 is energized and the gear head 3
7 axis rotates. A pulse generator 38 is attached to the shaft of the gear head 37, and a remaining amount sensor 39
A pulse is output. This pulse is used for remaining amount detection, which will be described later. The rotation of this shaft is caused by the shaft 40
The rotation causes the wire 42 to move.

The wire is engaged with tray 35 and the transfer paper is raised.

Next, a method for detecting the remaining amount will be explained with reference to FIG. When the tray 35 is raised by the drive of the paper feed table motor 36, the filler 46 attached to the lower part passes through the lower limit sensor 47. From that point on, pulses from the remaining amount sensor 39 begin to be counted, and the number of pulses until the transfer paper 34 pushes up the paper feed roller 48 and is detected by the upper limit sensor 49 is counted. Since the amount of movement of the tray 35 changes depending on the amount of transfer paper 34, the number of pulses changes accordingly to detect the remaining amount of transfer paper.

FIG. 7 shows the timing at this time.

When the maximum number of transfer sheets is loaded on the tray 35, the upper limit sensor 49 turns on before the tray 35 rises much, so the number of pulses is the minimum, and when there is no transfer paper on the tray, the number of pulses is the maximum. Therefore, the amount of transferred paper per pulse can be determined more easily. This value does not depend on the transfer paper size.

In order to express the usable time, it is further determined as follows.

Usable time = (maximum number of pulses - number of measured pulses) x (1
Amount of transfer paper per pulse) x (copying time) The usable time can be determined by setting the above copying time to be the copying time for the size of paper loaded on the tray.

(Effects) The present invention is as described above, and according to the present invention, since the remaining usage time that varies depending on the paper size can be displayed, the user is restrained in front of the copying machine during continuous copying in large quantities. You can allocate your time to other things without being overwhelmed.

[Brief explanation of the drawing]

Fig. 1 is a block diagram of the copying machine according to the present invention, Fig. 2 is a diagram showing the image forming area of the belt photoreceptor, Fig. 3 is a control block diagram of the image forming process, and Fig. 4 is a plan view of the operation display section. Figure, 5th
The figure is a perspective view of the appearance of the paper feed tray, FIG. 6 is a conceptual diagram of the paper feed section for explaining remaining amount detection, and FIG. 7 is a timing chart thereof. Figure 2 Figure 3 Figure 6 Akira Figure 7

Claims (1)

[Claims] A remaining amount detection means for detecting the remaining amount of transfer paper for transferring an original image, a means for calculating remaining continuous usable time from this data, original size data, and copying speed data, and a display thereof are provided. A remaining transfer paper amount display device for a copying machine, characterized in that the remaining amount of transfer paper is displayed in terms of usable time.