JPH08185059A - Electrophotographic device - Google Patents

Abstract

PURPOSE: To achieve the satisfactory measurement of toner print density from high to low density. CONSTITUTION: Distance sensors 27 and 28 are disposed opposite each other with a transfer belt 14 between them, and the circulating position of the transfer belt 14 is detected as positional data. The measurement results of the distance sensors 27 and 28, obtained when toner is not transferred to the transfer belt 14 and when the toner is transferred to it, and the positional data are synchronously stored, the thickness of toner transferred to the transfer belt 14 is calculated from the two measurement results according to the positional data, and the toner print density is measured from the thickness of the transferred toner.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electrophotographic apparatus for forming an image on printing paper by electrophotography.

[0002]

2. Description of the Related Art Currently, electrophotographic devices are used in laser printers, copying machines, facsimiles and the like. The electrophotographic apparatus forms an image on printing paper by an electrophotographic method.

That is, the surface of the photoconductor is uniformly charged by the discharge of the charging device, and the charged surface of the photoconductor is selectively discharged by the exposure of the exposure device to form an electrostatic latent image. This electrostatic latent image is developed by the toner supplied from the developing device, this toner is transferred to the printing paper conveyed by the paper conveying mechanism by the potential of the transfer device, and the toner transferred to this printing paper is transferred to the fixing device. It is fixed by heating and pressing.

There is also a model of such an electrophotographic apparatus in which a transfer belt is arranged between the photoconductor and the printing paper. In this case, the toner that developed the electrostatic latent image on the photoconductor is
The toner is transferred to an endless transfer belt stretched by a plurality of supporting rollers in a circulating manner, and the toner attached to the transfer belt is transferred to a printing paper. There is also a model that conveys printing paper by a conveyance belt as a paper conveyance mechanism. In this case, an endless transport belt is stretched around a plurality of support rollers in a circulatory manner, and printing paper is sequentially transported by the circulating transport belt.

In the electrophotographic apparatus as described above, in order to maintain a good quality of an image formed on a printing paper, the surface potential of the photoconductor is detected by a potential sensor before and after the exposure, and the density of the developed toner is detected. There is also a model in which the density is detected by a density sensor and the detected values are reflected in the control of the developing device, the exposing device, the transferring device, and the like.

[0006]

In the electrophotographic apparatus described above, the toner density is detected on the surface of the photoconductor in order to improve the image quality.

As a density sensor for detecting the toner density, an optical sensor such as a photodiode is generally used, but such an optical sensor does not have good detection characteristic linearity. For this reason, it is difficult to accurately detect the toner density from a low density to a high density, and the detection accuracy is lowered particularly when the toner has a high density.

Proposals aimed at solving such problems are disclosed in Japanese Patent Application Laid-Open Nos. 6-1861816 and 6-109643. For example, in the electrophotographic apparatus disclosed in JP-A-6-18816, the surface potential of the electrostatic latent image of the gradation density pattern formed on the photoconductor is detected by a potential sensor,
The developed gradation density pattern is read by an optical sensor, and the relational expression between the surface potential of the photoconductor and the toner adhesion amount is obtained. When the toner concentration is low, the optical sensor detects the toner concentration, and when the toner concentration is high, the toner concentration is calculated from the surface potential and the relational expression.

Further, in the electrophotographic apparatus disclosed in Japanese Patent Application Laid-Open No. 6-109643, an optical sensor reads the surface of a photosensitive member when toner is attached and when toner is not attached, and these reading results are logarithmically compressed. The toner density is calculated by the difference between when toner is attached and when toner is not attached.

Although the accuracy of detecting the toner density can be improved by the above-described processing, it is difficult to detect the toner density accurately because the reading result of the optical sensor is used in each case.

[0011]

According to the first aspect of the present invention,
The surface of the photoconductor is uniformly charged by the discharge of the charging device, and the surface of the charged photoconductor is selectively neutralized by the exposure of the exposure device to form an electrostatic latent image, and the electrostatic latent image is developed. Paper developed by toner supplied from a container, transferred to an endless transfer belt stretched by a plurality of supporting rollers in a circulating manner, and the toner attached to the transfer belt is conveyed by a paper conveyance mechanism. In the electrophotographic apparatus in which the toner transferred to the printing paper and fixed by the fixing device is fixed by the fixing device, two distance sensors are arranged at positions facing each other through the transfer belt, and the circulation position of the transfer belt is set to the position. Position detection means for detecting as data is provided, and first storage means for storing the measurement result of the distance sensor in synchronization with the position data in a state where toner is not transferred to the transfer belt is provided. Provided with a second storage unit for storing the measurement result of the distance sensor in synchronization with the position data in a state where the toner is transferred to the transfer belt, and stored in the first storage unit and the second storage unit. A thickness calculating means for calculating the thickness of the toner transferred to the transfer belt according to the position data from the two measurement results is provided.

According to a second aspect of the present invention, the surface of the photoconductor is uniformly charged by the discharge of the charger, and the charged surface of the photoconductor is selectively neutralized by the exposure of the exposure device to form an electrostatic latent image. To develop the electrostatic latent image with the toner supplied from the developing device, and transfer the toner to an endless transfer belt stretched by a plurality of supporting rollers in a circulating manner,
In an electrophotographic apparatus in which the toner attached to the transfer belt is transferred to a printing paper conveyed by a paper conveying mechanism and the toner transferred to the printing paper is fixed by a fixing device, the toner is attached to a position facing the outer surface of the transfer belt. One distance sensor is arranged, position detecting means for detecting the circulating position of the transfer belt as position data is provided, and the measurement result of the distance sensor is stored in synchronization with the position data in a state where toner is not transferred to the transfer belt. Second storage means for storing the measurement result of the distance sensor in synchronization with the position data in a state where the toner is transferred to the transfer belt, the first storage means and the second storage means. A thickness calculation means for calculating the thickness of the toner transferred to the transfer belt according to the position data from the two measurement results stored in the storage means. Digits.

According to the third aspect of the present invention, the surface of the photoconductor is uniformly charged by the discharge of the charger, and the charged surface of the photoconductor is selectively discharged by the exposure of the exposure device to form an electrostatic latent image. To develop the electrostatic latent image with the toner supplied from the developing device, and transfer the toner to an endless transfer belt stretched by a plurality of supporting rollers in a circulating manner,
In the electrophotographic apparatus in which the toner attached to the transfer belt is transferred to the printing paper conveyed by the paper conveyance mechanism and the toner transferred to the printing paper is fixed by the fixing device, the toner on the outer surface of the transfer belt is not transferred. A first distance sensor is arranged opposite to the position, a second distance sensor is arranged opposite to the position on the outer surface of the transfer belt where the toner is transferred, and position detection means for detecting the circulating position of the transfer belt as position data is provided. A first storage unit that stores the measurement results of the first distance sensor and the second distance sensor in synchronization with the position data in a state where the toner is not transferred to the transfer belt is provided, and the toner is transferred to the transfer belt. A second storage means for storing the measurement results of the first distance sensor and the second distance sensor in synchronization with position data in a closed state, Thickness calculating means for calculating a thickness of the toner transferred to the transfer belt according to the position data from the storage means and the second storage means and the two measurement results stored in the provided.

According to a fourth aspect of the invention, in the second or third aspect of the invention, the distance sensor is arranged at a position on the supporting roller so as to face the transfer belt.

According to a fifth aspect of the present invention, the surface of the photoconductor is uniformly charged by the discharge of the charger, and the charged surface of the photoconductor is selectively neutralized by the exposure of the exposure device to form an electrostatic latent image. The electrostatic latent image is developed with toner supplied from the developing device, and the printing paper is sequentially transported by the endless transport belt stretched by a plurality of supporting rollers in a circulating manner, and the printing is performed. In an electrophotographic apparatus in which toner developed on a sheet is transferred and the toner transferred on the printing sheet is fixed by a fixing device, a large number of through holes are continuously formed in the conveyor belt, and the through holes are formed through the through holes. Two distance sensors are arranged at positions facing each other, and a first storage means is provided for storing the measurement result of the distance sensor with respect to a portion of the printing paper conveyed by the conveyor belt on which the toner is not transferred. A second storage unit is provided for storing the measurement result of the distance sensor with respect to the portion of the printing paper conveyed by the conveyance belt on which the toner has been transferred, and two measurements stored in the first storage unit and the second storage unit are provided. A thickness calculating means for calculating the thickness of the toner transferred to the printing paper from the result is provided.

According to a sixth aspect of the present invention, the surface of the photoconductor is uniformly charged by the discharge of the charger, and the charged surface of the photoconductor is selectively neutralized by the exposure of the exposure device to form an electrostatic latent image. The electrostatic latent image is developed with toner supplied from the developing device, and the printing paper is sequentially transported by the endless transport belt stretched by a plurality of supporting rollers in a circulating manner, and the printing is performed. In an electrophotographic apparatus in which toner developed on a sheet is transferred and the toner transferred on the printing sheet is fixed by a fixing device, the conveyor belt is formed by a pair of endless belts arranged side by side with a gap between them. Two distance sensors are arranged at positions facing each other with a gap between the endless belts, and the distance sensor is used for the portion of the printing paper conveyed by the conveyor belt, on which the toner is not transferred. And a second storage means for storing the measurement result of the distance sensor with respect to a portion of the printing paper conveyed by the conveyor belt on which the toner is transferred. And a thickness calculation means for calculating the thickness of the toner transferred onto the printing paper from the two measurement results stored in the second storage means.

The invention according to claim 7 is the invention as defined in claims 1, 3, and 5.
Alternatively, in the invention described in 6, the measurement control means for simultaneously sampling the two distance sensors is provided.

The invention according to claim 8 is the invention as defined in claims 1, 3, and 5.
Alternatively, in the invention described in 6, the measurement control means for alternating the sampling timings of the two distance sensors is provided.

The invention according to claim 9 is the same as claim 1,
In the invention described in 3, 5, or 6, the operation control means for stopping the operation of the preset movable part when the two distance sensors are measured is provided.

[0020]

According to the first aspect of the present invention, the first storage means stores the measurement results of the two distance sensors facing each other via the transfer belt and the position data of the circulating position of the transfer belt detected by the position detection means. The toner is transferred to the transfer belt without being transferred, and the second storage means stores the toner when transferred to the transfer belt. The thickness calculation means calculates the thickness of the toner transferred to the transfer belt according to the position data from the two measurement results stored in the first storage means and the second storage means. The concentration is detected.

According to the second aspect of the present invention, the first storage means stores the measurement result of one distance sensor facing the outer surface of the transfer belt and the position data of the circulating position of the transfer belt detected by the position detection means. The toner is stored in the state where the toner is not transferred to the transfer belt, and the second storage means stores the state in which the toner is transferred to the transfer belt. The thickness calculation means calculates the thickness of the toner transferred to the transfer belt according to the position data from the two measurement results stored in the first storage means and the second storage means. The concentration is detected.

According to the third aspect of the present invention, the measurement result of the first distance sensor, which is arranged to face the outer surface of the transfer belt at a position where the toner is not transferred, and the position of the outer surface of the transfer belt, where the toner is transferred, are arranged to face each other. The first storage means stores the measurement result of the second distance sensor and the position data of the circulating position of the transfer belt detected by the position detection means in a state where the toner is not transferred to the transfer belt, and the second storage means , Stores the toner after it is transferred to the transfer belt. The thickness calculation means calculates the thickness of the toner transferred to the transfer belt according to the position data from the two measurement results stored in the first storage means and the second storage means. The concentration is detected.

According to the fourth aspect of the invention, since the distance sensor faces the transfer belt at the position on the support roller, the transfer belt is properly positioned by the support roller at the measurement position of the distance sensor.

According to the fifth aspect of the invention, when two distance sensors facing each other through a large number of through holes continuously formed on the conveyor belt measure a portion of the printing paper on which the toner is not transferred, The first storage means stores the measurement result, and when the toner-transferred portion of the printing paper is measured,
The second storage means stores the measurement result. The thickness calculation means calculates the thickness of the toner transferred to the printing paper from the two measurement results stored in the first storage means and the second storage means. Therefore, the print density of the toner is detected by this thickness. To be done.

According to the sixth aspect of the present invention, when the two distance sensors facing each other across the gap of the pair of endless belts forming the conveyor belt measure the portion of the printing paper on which the toner is not transferred, this measurement is performed. The first storage means stores the result, and when the toner-transferred portion of the printing paper is measured, the second storage means stores the measurement result. The thickness calculation means calculates the thickness of the toner transferred to the printing paper from the two measurement results stored in the first storage means and the second storage means. Therefore, the print density of the toner is detected by this thickness. To be done.

In the seventh aspect of the invention, since the measurement control means sets the sampling timings of the two distance sensors at the same time, the two distance sensors measure the same position of the transfer belt and the conveyance belt.

In the eighth aspect of the present invention, the measurement control means alternates the sampling timings of the two distance sensors, so that the measurement operations of the two distance sensors do not interfere with each other.

In the ninth aspect of the invention, since the operation control means stops the operation of the preset movable portion when measuring the two distance sensors, the vibration of the movable portion impairs the measurement accuracy of the distance sensor. There is no.

[0029]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of the present invention will be described below with reference to FIGS. First, as shown in FIG. 1, the digital copying machine 1 which is the electrophotographic apparatus of this embodiment has an image reading section 2 and an image forming section 3. The image reading unit 2 is configured by connecting an image processing circuit 5 to an image scanner 4, and the image processing circuit 5 includes the image forming unit 3
Is connected to a laser scanner 6 which is an exposure device.

The image forming section 3 has a rotatable photosensitive drum 7 as a photosensitive member. On the outer peripheral surface of the photosensitive drum 7, a drum cleaner 8, a discharging lamp 9, a charging device 10, the laser scanner 6, a potential sensor 11, a developing device 12, an optical sensor 13, and a transfer belt 14 are sequentially arranged to face each other. There is. The transfer belt 14 is formed in an endless manner and is stretched around a plurality of support rollers 15 so as to be able to circulate. A belt cleaner 16 and a transfer device 17 are arranged opposite to each other on the outer surface of the transfer belt 14.

A sheet conveying path 18 communicates with a gap between the transfer device 17 and the transfer belt 14, and the sheet conveying path 18 communicates with a sheet feeding cassette 19 to a sheet discharging tray 20. At a position facing the paper feed cassette 19,
A paper feed mechanism 22 is provided as part of the paper transport mechanism 21, and a part of the paper transport mechanism 21 is provided at a position where the paper feed mechanism 22 communicates from the gap between the transfer device 17 and the transfer belt 14 to the paper discharge tray 20. Belt transport mechanism 23 and fixing device 2
4 are sequentially arranged. The belt transport mechanism 23
Has an endless conveyor belt 25, and the conveyor belt 25 is stretched around a plurality of support rollers 26 in a circulatory manner.

In the digital copying machine 1 of this embodiment, as shown in FIGS. 1 and 2, two laser displacement gauges 27 and 28, which are distance sensors, face each other with the transfer belt 14 interposed therebetween. A distance measuring unit 29 is connected to the laser type displacement gauges 27 and 28. As shown in FIG. 2, a rotary encoder 30 is connected to one of the support rollers 15 around which the transfer belt 14 is stretched.
A rotation amount detection unit 31 is connected to.

Further, as shown in FIG. 3, the potential sensor 11, the optical sensor 13, the distance measuring unit 29, the rotation amount detecting unit 31, the driving unit 32 of the photosensitive drum 7,
The drive unit 33 of the transfer belt 14 and the transport belt 25
The drive unit 34, the drive unit 35 of the paper feed mechanism 22, and the drive unit 36 of the transfer device 17 are connected to an I / O (Input / Output) control unit 37. Is
The information processing unit 38 is connected.

The information processing section 38 is a CPU (Central P
rocessing unit), ROM (Read Only Memory), RAM
It is composed of a microcomputer having (Random Access Memory), and executes various data processing based on various data input from the potential sensor 11, the optical sensor 13, the distance measuring unit 29, and the rotation amount detecting unit 31. ,
The drive unit 32 by executing various data processing
Control the operations of 36 and so on.

The laser type displacement meter 27 outputs a signal corresponding to the distance from the front surface of the transfer belt 14, and the laser type displacement meter 28 corresponds to the optical distance from the rear surface of the transfer belt 14. Since the output signal is output, the distance measuring unit 29 and the information processing unit 38 are based on the output signal.
Perform information processing set in advance. Further, since the rotary encoder 30 outputs a signal in synchronization with the circulation of the transfer belt 14, the rotation amount detection unit 31 and the information processing unit 38 perform information processing preset based on the output signal. Run.

Therefore, in the digital copying machine 1 of this embodiment, the pattern forming means, the measurement control means, the first thickness detecting means, the second thickness detecting means, the position detecting means, the first storing means,
Second storage means and thickness calculation means are provided.

As shown in FIG. 5B, the pattern forming means transfers the toner 39 to the transfer belt 14 as a test pattern preset as a rectangular image having the highest density. Two of the laser type displacement gauges 27, 28
The measurement operation of is dynamically executed at regular intervals with respect to the circulating transfer belt 14, but the measurement control means sets the sampling timings of the two laser displacement meters 27 and 28 at the same time.

The first thickness detecting means detects the thickness of the transfer belt 14 in a state where the toner 39 is not transferred, from the measurement results of the laser displacement gauges 27 and 28, and this is used as the first thickness. Output as data. The second thickness detecting means uses the measurement results of the laser displacement gauges 27 and 28 to transfer the transfer belt 14 with the toner 39 transferred.
The thickness of the sheet is detected and this is output as the second thickness data. The position detecting means includes the rotary encoder 3
The circulating position of the transfer belt 14 is detected based on the measurement result of 0, and this is output as position data.

The first storage means stores the first thickness data as the measurement results of the laser displacement meters 27 and 28 in synchronization with the position data, and the second storage means stores the second thickness data. The measurement results of the laser displacement meters 27 and 28 are stored in synchronization with the position data. Then, the thickness calculating means uses the two measurement results stored in the first storage means and the second storage means in accordance with the position data to transfer belt 1
The thickness of the toner 39 transferred to No. 4 is calculated. More specifically, the transfer belt 1 is obtained by subtracting the first thickness data from the second thickness data in correspondence with the position data.
The thickness of the toner 39 transferred to No. 4 is calculated.

In the digital copying machine 1 of this embodiment having such a configuration, the image of the original 40 is read by the image reading unit 2, and the image is formed by the image forming unit 3 on the printing paper 41.
Copy to.

More specifically, in the image reading section 2, the document 4
Since the image of 0 is optically scanned by the image scanner 4 and converted into image data, this image data is transmitted from the image processing circuit 5 to the laser scanner 6 of the image forming unit 3.

At this time, in the image forming section 3, the surface of the rotating photosensitive drum 7 is uniformly charged by the discharge of the charger 10. Therefore, the surface of the rotating photosensitive drum 7 is charged according to the image data. It is exposed by the operating laser scanner 6. By this exposure, the charged surface of the photosensitive drum 7 is selectively discharged to form an electrostatic latent image.
The electrostatic latent image is developed by the toner 39 supplied from the developing device 12, and the measured toner 39 is transferred to the transfer belt 14.

At this time, the printing paper 41 is fed from the paper feed cassette 19 to the paper transport path 18 by the paper feed mechanism 22, so that the toner 39 transferred to the transfer belt 14 is transferred to the transfer device 1.
It is transferred to the printing paper 41 by the potential of 7. The printing paper 41 to which the toner 39 has been transferred is conveyed to the fixing device 24 by the conveying belt 25, so that the toner 39 is pressed and heated by the fixing device 24 and is thus heated.
Settles to 1.

The printing paper 41, on which the toner 39 is fixed, is discharged onto the paper discharge tray 20 to complete the copying operation of the digital copying machine 1. The toner 39 remaining on the surface of the rotating photosensitive drum 7 is removed by the drum cleaner 8, and the toner 39 remaining on the surface of the circulating transfer belt 14 is removed by the belt cleaner 16.

As described above, the digital copying machine 1 transfers the toner 39 onto the printing paper 41 by electrophotography to form an image. The printing density of the toner 39 changes with time in the electrostatic characteristic of the photosensitive drum 7. And changes due to environmental changes. However, the digital copying machine 1 of the present embodiment detects the print density of the toner 39 in the initial setting at the time of startup, and controls the drive voltage of the charging device 10, the developing device 12, and the transfer device 17 correspondingly. Thus, the print density of the toner 39 is constantly corrected.

Therefore, the processing operation for detecting the print density of the toner 39 in order to execute such a correction operation will be described with reference to FIG.
And it demonstrates below one by one based on FIG. First, as shown in FIG. 4, the thickness of the circulating transfer belt 14 is sequentially detected as the first thickness data “DT3” by the measurement results of the laser displacement meters 27 and 28, and the rotary encoder 30 of the transfer belt 14 is detected. It is stored together with the position data detected by the measurement result of. At this time, as shown in FIG.
Since the distance "DT0" between the two laser displacement meters 27 and 28 is preset as an initial value, the laser displacement meter 2
The measurement result "DT1, DT2" of each of 7 and 28 is changed to "DT
By subtracting from "0", the first thickness data "DT
3 ″ is calculated.

Next, as shown in FIG. 5B, a test pattern set as a rectangular image of the highest density is formed on the photosensitive drum 7 with toner 39, and this toner 39 is transferred onto the circulating transfer belt 14. It As shown in FIG. 4, the thickness of the transfer belt 14 which circulates in a state where the toner 39 is transferred is sequentially detected as the second thickness data “DT3 ′” by the measurement results of the laser displacement meters 27 and 28. , And is stored together with the position data detected by the measurement result of the rotary encoder 30 of the transfer belt 14.

Then, the stored data accumulated as described above is called, and the first thickness data "DT3" is subtracted from the second thickness data "DT3 '" by making the position data correspond to each other. As shown in FIG. 5A, the thickness of the toner 39 transferred to the transfer belt 14 is calculated as toner thickness data “TD”.

The toner thickness data “TD” indicating the thickness of the toner 39 indicates the amount of the toner 39 attached, and also indicates the print density of the toner 39. Therefore, in the digital copying machine 1 of the present embodiment, the charging device 10, the developing device 12, and the transfer device 1 are based on the detected toner thickness data "TD".
By controlling the drive voltage of No. 7, the print density of the toner 39 is corrected to be constant.

Since the digital copying machine 1 of this embodiment measures the print density of the toner 39 by the transferred thickness as described above, the print density of the toner 39 is detected as compared with the case where it is optically read. The accuracy is good, and the print density of the toner 39 can be measured with good characteristics from low density to high density. Moreover, the thickness of the toner 39 is set to the transfer belt 1
Although the thickness of the transfer belt 14 is measured separately, the thickness of the transfer belt 14 is also measured separately and the position is synchronized and subtracted.
The influence of the error in the thickness of the transfer belt 14 and the curvature is eliminated, and the measurement accuracy of the thickness of the toner 39 is good.

In the digital copying machine 1 of this embodiment, the measurement results of the two laser type displacement gauges 27 and 28 are sampled at the same time, so that the two laser type displacement gauges 27 and 28 are used.
Means that the same position of the transfer belt 14 is measured, and the thickness of the toner 39 can be accurately measured.

Further, in the digital copying machine 1 of this embodiment,
It was assumed that the test pattern transferred to the transfer belt 14 in order to detect the thickness of the toner 39 is a rectangular pattern with the highest density, but the present invention is not limited to the above-described embodiment, and for example, this It is also possible to form such a test pattern in stepwise multi-gradation.

Further, in the digital copying machine 1 of the present embodiment, it has been illustrated that only one set of two laser type displacement gauges 27, 28 is provided, but the present invention is not limited to the above embodiment, For example, a plurality of sets of two laser displacement meters 2
7, 28 are arranged in series to adjust the thickness of the toner 39 to the transfer belt 14.
It is also possible to assume multiple positions.

In the digital copying machine 1 of this embodiment,
The laser scanner 6 is also used when measuring the laser displacement gauges 27 and 28.
However, there is a concern that the vibration due to the operation of such a movable part may lower the measurement accuracy of the laser displacement meters 27 and 28.

Therefore, when such a problem arises, the digital copying machine 1 is provided with an operation control means to stop the operation of the preset movable part when the laser displacement meters 27 and 28 are measured. It is preferable. More specifically,
As shown in FIG. 6, the operation of the movable part is stopped immediately before the measurement operation of the laser displacement meters 27 and 28, and the laser displacement meter 2
When the measurement operations of 7 and 28 are completed, the operation of the movable part is restarted.

The vibration of the operation of the movable portion to be stopped affects the measurement accuracy of the laser displacement meters 27 and 28, and even if the operation is stopped, the measurement operation of the laser displacement meters 27 and 28 is not hindered. The image scanner 4, the laser scanner 6, the drum cleaner 8, the developing device 12, the paper transport mechanism 21, and the like are the parts. Although it is assumed here that the operation of the photosensitive drum 7 and the transfer belt 14 is not stopped, the measurement operation of the laser displacement meters 27 and 28 is quickly completed, but when the detection accuracy is more important than the operation time. In particular, it is preferable to stop all the movable parts when the measurement operation of the laser displacement meters 27 and 28 is executed.

Further, in the digital copying machine 1 of this embodiment,
By sampling the measurement results of the two laser type displacement gauges 27 and 28 at the same time, the two laser type displacement gauges 2
It is exemplified that the thickness of the toner 39 is precisely measured by measuring the same position of the transfer belt 14 with Nos. 7 and 28. But,
The laser type displacement meters 27 and 28 transfer the laser light to the transfer belt 1
The distance from the transfer belt 14 is measured by receiving the laser light emitted to each of the four laser beams and reflected respectively, so that when the transfer belt 14 is transmissive, the measurement accuracy is improved by the interference of the other laser light. descend.

Therefore, when such a problem occurs, the two laser type displacement gauges 27,
It is preferable to alternate 28 sampling timings. More specifically, as shown in FIG. 7, first, the measurement result “DT1” of the laser displacement meter 27 is sampled and stored together with the position data, and then the laser displacement meter 2 is measured.
The measurement result “DT2” of 8 is sampled and stored.
These "DT1, DT2" are laser displacement meters 27, 28
The first thickness data "DT" is subtracted from the interval "DT0" of
3 "is calculated and stored together with the position data. In this case,
Since the light emission of one of the laser displacement meters 27 and 28 does not interfere with the light reception of the other, the measurement can be performed with high accuracy even when the transfer belt 14 has transparency.

It should be noted that if the measurement results of the two laser type displacement gauges 27 and 28 are alternately sampled as described above with respect to the continuously circulating transfer belt 14, the two laser type displacement gauges are displaced. Transfer belt 14 is a total of 27 and 28.
Since the same position cannot be measured, there is a concern that the measurement accuracy may decrease due to this. However, this is the transfer belt 14
By setting the sampling interval of the laser type displacement gauges 27 and 28 to be sufficiently high with respect to the circulation speed of, the problem can be avoided in the practical range.

Further, as shown in FIG. 8, if the two laser displacement gauges 27 and 28 are alternately measured while the transfer belt 14 serving as a movable portion is stopped, the detection accuracy due to the interference of laser light can be improved. The transfer belt 14 while preventing the deterioration
The same position can be measured. In this case, the processing speed is reduced, but the above-mentioned problem is completely solved, so that the measurement operation can be executed with extremely high accuracy.

That is, two laser displacement meters 27, 2
Whether to set the sampling timings of 8 simultaneously or alternately is selected in consideration of the transparency of the transfer belt 14, the detection accuracy, the processing speed, and the like.

Next, a second embodiment of the present invention will be described below with reference to FIGS. 9 and 10. With respect to the digital copying machine (not shown) shown in this embodiment, the same parts as those of the digital copying machine 1 described as the first embodiment are designated by the same names and reference numerals, and detailed description thereof will be omitted. .

First, in the digital copying machine of this embodiment, one laser type displacement meter 27 is arranged at a position facing the outer surface of the transfer belt 14, and a laser type displacement meter 28 facing the inner surface of the transfer belt 14. Is not provided. The transfer belt 14 is stretched around a plurality of support rollers 15 so as to be able to circulate, but the laser displacement meter 27 is arranged at a position on one support roller 15 so as to face the transfer belt 14.

In the digital copying machine of this embodiment,
The measurement result of one laser type displacement meter 27 facing the outer surface of the transfer belt 14 and the position data of the transfer belt 14 are
The first storage means stores the toner 39 in a state where the toner 39 is not transferred to the transfer belt 14, and the second storage means stores the transfer belt 14.
The toner is transferred and stored in the memory. Then, the thickness calculating means subtracts the first measurement result from the second measurement result in correspondence with the position data, and thereby the transfer belt 14
The thickness of the toner 39 transferred to is calculated.

With such a configuration, in the digital copying machine of this embodiment, when the print density of the toner 39 is detected, the toner 39 is transferred to the transfer belt 14 as shown in FIG.
The measurement result “DT1” of the laser displacement meter 27 is stored together with the position data in a state where the transfer belt 1 is not transferred.
Laser displacement meter 27 with toner 39 transferred to No. 4
The measurement result "DT1 '" is stored together with the position data. Then, these stored data are called, and the first measurement result “DT1” is subtracted from the second measurement result “DT1 ′” in correspondence with the position data, whereby the toner 39 transferred onto the transfer belt 14 is The thickness is calculated as toner thickness data "TD".

In the digital copying machine of this embodiment, the printing density of the toner 39 is set to one laser displacement meter 27 as described above.
Since it is measured based on the measurement result of, the structure is simple and it can contribute to the reduction of size and weight and the improvement of productivity. Since the number of data to be handled and the arithmetic processing to be executed are small, the data processing is simple and the processing operation can be speeded up. Is. Moreover, the toner 39
Is measured together with the thickness of the transfer belt 14,
Since the thickness of the transfer belt 14 is also measured separately and the position is synchronized and subtracted, the influence of the error in the thickness of the transfer belt 14 and the curvature are eliminated, and the measurement accuracy of the thickness of the toner 39 is excellent. Is.

In the digital copying machine of this embodiment, the laser displacement meter 27 is one, but this is the support roller 1.
5, the transfer belt 14 is opposed to the transfer belt 14 at a position above the transfer belt 14, so that the transfer belt 14 is supported by the support roller 1
It is well positioned by the laser displacement meter 2
The measurement accuracy of 7 is good.

Also in the digital copying machine of this embodiment, as shown in FIG. 11, the operation of the movable portion can be stopped by the operation control means when the laser displacement meter 27 is measured.

Next, a third embodiment of the present invention will be described below with reference to FIGS. Regarding the digital copying machine (not shown) shown in this embodiment, the same parts as those of the digital copying machine described as the second embodiment are designated by the same names and reference numerals and detailed description thereof will be omitted.

First, in the digital copying machine of the present embodiment, the first laser displacement meter 42, which is the first distance sensor, is arranged opposite to the side edge of the outer surface of the transfer belt 14 where the toner 39 is not transferred. A second laser type displacement meter 43, which is a second distance sensor, is arranged opposite to the central portion of the outer surface of the belt 14 to which the toner 39 is transferred.

In the digital copying machine of this embodiment,
The first offset detecting means detects the offset amount of the surface of the transfer belt 14 in a state where the toner 39 is not transferred, from the measurement results of the first and second laser displacement meters 42 and 43, Output as offset data.
The second offset detecting means detects the offset amount of the surface of the transfer belt 14 in the state where the toner 39 is transferred from the measurement results of the first and second laser displacement meters 42 and 43, and this is used as the second offset. Output as data.

The first storage means stores the first offset data as the measurement results of the first and second laser displacement meters 42 and 43 in synchronization with the position data, and the second storage means:
The second offset data is stored as the measurement results of the first and second laser displacement meters 42, 43 in synchronization with the position data. The thickness calculating means calculates the thickness of the toner 39 transferred to the transfer belt 14 by correlating the position data and subtracting the first offset data from the second offset data.

With such a configuration, in the digital copying machine of this embodiment, when the print density of the toner 39 is detected, the toner 39 is transferred to the transfer belt 14 as shown in FIG.
The first offset data “K” is calculated by subtracting the measurement result “DT2” of the second laser type displacement meter 43 from the measurement result “DT1” of the first laser type displacement meter 42 in a state in which is not transferred. Next, with the toner 39 transferred to the transfer belt 14, the measurement result “D
The measurement result of the second laser displacement meter 43 from "T1" to "DT
By subtracting 2 "and subtracting the first offset data" K "from the second offset data" K '", the toner thickness data" TD "is calculated.

The digital copying machine of this embodiment measures the print density of the toner 39 by the measurement results of the first and second laser displacement meters 42 and 43 as described above.
Both of the second laser type displacement meters 42 and 43 are transfer belts 14.
Since it is arranged outside, the structure is simple and it can contribute to productivity improvement. Moreover, although the thickness of the toner 39 is measured together with the thickness of the transfer belt 14, the thickness of the transfer belt 14 is also measured separately and the position is synchronized and subtracted. The influence of the curvature and the like is eliminated, and the measurement accuracy of the thickness of the toner 39 is good.

In the digital copying machine of this embodiment, since the laser displacement meters 42 and 43 face the transfer belt 14 at the position on the support roller 15, the laser displacement meters 42 and 4 are arranged.
The transfer belt 14 is favorably positioned by the support roller 15 at the measurement position 3 of the laser type displacement gauges 42, 43.
The measurement accuracy of is good.

Also in the digital copying machine of this embodiment, as shown in FIG. 14, the operation of the movable portion can be stopped by the operation control means when the laser displacement meters 42 and 43 are measured.

Next, a fourth embodiment of the present invention will be described below with reference to FIGS. With respect to the digital copying machine shown in this embodiment, the same parts as those of the digital copying machine 1 described as the first embodiment are designated by the same names and reference numerals, and detailed description thereof will be omitted.

First, in the digital copying machine 44 which is the electrophotographic apparatus of the present embodiment, as shown in FIG. 15, the laser displacement gauge is not provided at the position facing the transfer belt 14, and as shown in FIG. As shown in FIG. 17, a large number of through holes 46 are continuously formed in the center of an endless conveyor belt 45 stretched in a circulating manner.
As shown in FIG. 7, laser type displacement gauges 47, 4 are provided as two distance sensors at positions facing each other through these through holes 46.
8 are arranged. These laser displacement meters 47, 4
8 is connected to a distance measuring unit 49, and the distance measuring unit 49 is connected to the information processing unit 38 via the I / O control unit 37.
It is connected to the.

Further, a rotary encoder (not shown) is connected to one of the support rollers 26 around which the conveyor belt 45 is stretched, and as shown in FIG. 16, the rotation amount detection connected to this rotary encoder. Part 50 is also I
It is connected to the information processing unit 38 via the / O control unit 37.

The laser displacement meter 47 outputs a signal corresponding to the distance from the front surface of the conveyor belt 45, and the laser displacement meter 48 corresponds to the optical distance from the rear surface of the conveyor belt 45. Since the output signal is output, the distance measuring unit 49 and the information processing unit 38 are output based on the output signal.
Perform information processing set in advance. Further, since the rotary encoder outputs a signal in synchronization with the circulation of the conveyor belt 45, the rotation amount detection unit 50 and the information processing unit 38 execute preset information processing based on the output signal. To do.

In the digital copying machine 44 of the present embodiment, the print density of the toner 39 is detected by the thickness of the transferred toner 39 as in the digital copying machine 1 described above.
As shown in (b), the toner 39 for detecting the thickness is transferred to the central portion of the printing paper 41 and is not transferred to the front end portion and the rear end portion.

Therefore, when the position detecting means outputs position data in accordance with the circulating position of the conveyor belt 45, the two laser displacement meters 47,
The measuring operation 48 is executed at the position of the through hole 46 of the conveyor belt 45, which is circulated.

Printing paper 4 conveyed by the conveyor belt 45.
The first storage means stores the measurement results of the laser displacement meters 47 and 48 for the front end portion and the rear end portion to which the toner 39 of No. 1 is not transferred, and the toner 39 of the printing paper 41 conveyed by the conveyor belt 45. Since the second storage means stores the measurement results of the laser displacement gauges 47, 48 for the central portion to which is transferred, the thickness calculation means stores the two results stored in the first storage means and the second storage means. The thickness of the toner 39 transferred to the printing paper 41 is calculated from the measurement result.

More specifically, when the two laser type displacement gauges 47, 48 execute the measurement operation, the measurement control means alternates the sampling timings of the two laser type displacement gauges 47, 48. To do. The first thickness detecting means determines the printing paper 4 based on the measurement results of the laser displacement gauges 47 and 48.
The first thickness data "DT3" is output by detecting the thickness of the portion where the toner 39 of No. 1 is not transferred. This first thickness data "DT3" is until the printing paper 41 is actually detected. Is "0". Therefore, the thickness comparison means successively compares the preset representative value "SW0" of the thickness of the printing paper 41 and the first thickness data "DT3", and if the values are within the allowable range, the toner 39 of the printing paper 41 is compared. The first thickness data “D
T3 ″ is captured.

Next, the second thickness detecting means detects the thickness of the central portion of the printing paper 41 on which the toner 39 is transferred from the measurement results of the laser type displacement gauges 47 and 48 to obtain the second thickness data. Although "DT3 '" is output, in this case, the central portion of the printing paper 41 on which the toner 39 is transferred is recognized according to the position data.

Similarly, according to the position data, the printing paper 41
When the rear end portion to which the toner 39 of the above is not transferred is recognized, the first thickness detecting means causes the laser displacement meter 4
The thickness of the portion of the printing paper 41 on which the toner 39 is not transferred is detected from the measurement results of Nos. 7 and 48, and the first thickness data "DT3""is output. Two first thickness data “DT3” from the part
Since "DT3""is detected, the first thickness detecting means is
Finally, the regular first thickness data "SW1" is calculated as an average value of the two first thickness data.

The first storage means stores the first thickness data "SW1" as the measurement result of the laser displacement meters 47 and 48, and the second storage means stores the second thickness data "DT".
Since 3 '"is stored as the measurement result of the laser type displacement gauges 47 and 48, the thickness calculating means uses the two measurement results stored in the first storage means and the second storage means to print the print sheet 4
The thickness of the toner 39 transferred to 1 is calculated. More specifically, the printing paper 41 is obtained by subtracting the first thickness data "SW1" from the second thickness data "DT3 '".
The thickness of the toner 39 transferred to is calculated.

With such a configuration, in the digital copying machine 44 of the present embodiment, when the print density of the toner 39 is detected, as shown in FIG. 19B, the test pattern set as the rectangular image of the maximum density. The toner 39 is transferred onto the printing paper 41, and the printing paper 41 on which the toner 39 is transferred is transported by the transport belt 45.

Then, as shown in FIG. 18, the laser displacement gauges 47 and 48 start measurement at a predetermined timing.
These laser type displacement gauges 47 and 48 are provided in the through hole 4 of the conveyor belt 45 until the printing paper 41 reaches the measurement position.
6 will be detected. Therefore, the calculation process “DT3 = DT0− (DT1 + D) for detecting the thickness of the printing paper 41 is performed.
T2) "indicates that the laser displacement gauges 47 and 48 are the printing paper 41.
It does not approximate to the preset representative value "SW0" until it detects.

Therefore, when "DT3≈SW0" is reached, it is assumed that the laser displacement meters 47 and 48 have detected the leading edge of the printing paper 41, and the thickness of the portion of the printing paper 41 on which the toner 39 has not been transferred. First thickness data “DT
3 "is detected. At this time, as shown in FIG. 16, since the interval" DT0 "between the two laser type displacement gauges 47, 48 is preset as an initial value, the laser type displacement gauge 47, 48 is detected.
Each measurement result "DT1, DT2" of 48 is "DT0"
By subtracting from, the first thickness data “DT3” is calculated.

Next, as shown in FIG. 18, the central portion of the printing paper 41 on which the toner 39 is transferred is recognized according to the position data, and the laser displacement meter 47,
From the 48 measurement results “DT1, DT2”, print paper 41
The second thickness data "DT3 '" indicating the thickness of the portion to which the toner 39 is transferred is detected. Further, the rear end portion of the printing paper 41 on which the toner 39 is not transferred is recognized according to the position data, and the laser type displacement meter 47,
The first thickness data "DT3""is detected from the 48 measurement results" DT1, DT2 ".

Next, these two first thickness data "D
The formal first thickness data "SW1" is calculated as the average value of T3 "" DT3 "", and the second thickness data "DT3 '" is calculated.
By subtracting from, as shown in FIG.
The thickness of the toner 39 transferred onto the printing paper 41 is calculated as toner thickness data “TD”.

Since the digital copying machine 44 of this embodiment measures the print density of the toner 39 by the transferred thickness as described above, the print density of the toner 39 is detected as compared with the case of being optically read. The accuracy is good, and the print density of the toner 39 can be measured with good characteristics from low density to high density.

Moreover, the thickness of the toner 39 is set to the printing paper 41.
However, since the thickness of the printing paper 41 is also separately measured and subtracted, the influence of the thickness error of the printing paper 41, the curvature, etc. is eliminated, and the thickness of the toner 39 is The measurement accuracy of is good. Further, the printing paper 41 on which the toner 39 is transferred is positioned on the conveyor belt 45, but the measurement operation of the laser displacement meters 47 and 48 is executed through the through hole 46 formed in the conveyor belt 45. The measurement results of the laser displacement meters 47 and 48 are not affected by the thickness of the conveyor belt 45 and the separation of the printing paper 41 from the conveyor belt 45.

The first thickness data detected from these two portions is averaged to calculate the regular first thickness data, with the portions where the toner 39 is not transferred as the leading edge portion and the trailing edge portion of the printing paper 41. Therefore, the detection accuracy of the first thickness data is good. The digital copying machine 4 of this embodiment
In FIG. 4, since the representative value “SW0” of the thickness of the printing paper 41 is preset, if the detection of the first thickness data “SW1” fails, the representative value “SW0” can be used instead. Is.

In the digital copying machine 44 of this embodiment, it is assumed that the thickness uniformity of the printing paper 41 is sufficient and the first thickness data and the second thickness data are printed.
Since it is detected from different portions of 1, the influence of the nonuniformity of the thickness of the printing paper 41 cannot be excluded from the measurement result. Therefore, when such a problem arises, for example, a set of laser displacement gauges is arranged in a portion that communicates from the paper feed mechanism 22 to the transfer device 17, and the printing paper is transferred before the toner 39 is transferred. It is preferable that the first thickness data 41 is stored together with the position data, and the toner thickness data is detected by associating the second thickness data of the portion to which the toner 39 is transferred with the position data.

In the digital copying machine 44 of the present embodiment, one of the two laser displacement meters 47, 48 emits light by alternately sampling the measurement results of the two laser displacement meters 47, 48. Prevents the measurement accuracy from deteriorating due to interference with the other received light. By alternately sampling the measurement results of the two laser displacement meters 47 and 48 in this way for the continuously circulating transport belt 45, the two laser displacement meters 47 and 48 print. Since it is not possible to measure the same position on the paper 41, there is a concern that the measurement accuracy may drop due to this. However, this is due to the fact that the laser displacement gauges 47, 48 are different from the circulation speed of the conveyor belt 45.
By setting the sampling interval of (1) to a sufficiently high speed, it is possible to avoid problems in the practical range.

Further, in the digital copying machine 44 of the present embodiment, it is assumed that the test pattern transferred to the printing paper 41 in order to detect the thickness of the toner 39 is a rectangular pattern having the highest density. Is not limited to the above-described embodiment, and it is possible to form such a test pattern in a multi-step gradation.

Further, in the digital copying machine 44 of the present embodiment, only one set of two laser type displacement gauges 47 and 48 is provided, but the present invention is not limited to the above embodiment. For example, a plurality of sets of two laser displacement meters 4
7, 48 are connected in series to adjust the thickness of the toner 39 to the conveyor belt 45.
It is also possible to assume multiple positions.

Further, in the digital copying machine 44 of the present embodiment, the movable part such as the laser scanner 6 can be operated even when the laser displacement meters 47 and 48 are measured, but the vibration due to the operation of the movable part is laser type. There is a concern that the measurement accuracy of the displacement gauges 47 and 48 may be reduced.

Therefore, when such a problem occurs, an operation control means is provided in the digital copying machine 44 to stop the operation of the preset movable part when the laser displacement meters 47 and 48 are measured. It is preferable. More specifically, as shown in FIG. 20, the operation of the movable part is stopped immediately before the measurement operation of the laser displacement meters 47 and 48, and when the measurement operation of the laser displacement meters 47 and 48 is completed, Resume operation.

The vibration of the operation of the movable part to be stopped affects the measurement accuracy of the laser displacement meters 47 and 48, and even if the operation is stopped, the measurement operation of the laser displacement meters 47 and 48 is not hindered. The image scanner 4, the laser scanner 6, the drum cleaner 8, the developing device 12, the paper transport mechanism 21, and the like are the parts. In addition, here, it is assumed that the operation of the photosensitive drum 7 and the conveyor belt 45 is not stopped so that the measurement operation of the laser displacement meters 47 and 48 is quickly completed, but when the detection accuracy is more important than the operation time. In addition, it is preferable to stop all the movable parts when the measurement operation of the laser displacement meters 47 and 48 is executed.

Further, in the digital copying machine 44 of this embodiment, the measuring operations of the two laser type displacement gauges 47 and 48 are alternately performed in order to prevent the interference of the laser light as described above. If the measurement of the two laser displacement gauges 47 and 48 is alternately performed while the transport belt 45 is stopped as a movable part, the detection accuracy of the transport belt 45 can be prevented from being lowered due to the interference of the laser light. Can measure the same position. In this case, the processing speed is reduced, but the above-mentioned problem is completely solved, so that the measurement operation can be executed with extremely high accuracy.

Further, in the digital copying machine 44 of this embodiment, since the thickness of the printing paper 41 conveyed by the conveyor belt 45 is measured by the laser displacement gauges 47 and 48, the conveyor belt 45 is continuously penetrated with a through hole. However, the present invention is not limited to the above embodiment.

For example, as a fifth embodiment of the present invention, as shown in FIG. 21, a conveyor belt 54 is formed by a pair of endless belts 52, 53 arranged side by side with a gap 51, and these endless belts are formed. 52, 53 gap 51
Two laser type displacement gauges 47, 4 at positions facing each other via
It is also possible to arrange eight. In this case, it is not necessary to synchronize the measurement timings of the laser displacement meters 47 and 48 with the through holes 46 of the conveyor belt 45, so that the measurement operation can be performed more easily. It is possible to assume that the lateral width of the gap 51 affects the measurement result, but this does not interfere with the measurement of the laser displacement meters 47 and 48.
Can be made sufficiently small so that there is no problem in practical use.

[0106]

According to the first aspect of the present invention, two distance sensors are arranged at positions facing each other via the transfer belt, and position detecting means for detecting the circulating position of the transfer belt as position data is provided. A first storage means is provided for storing the measurement result of the distance sensor in synchronization with the position data in the state where the toner is not transferred, and the measurement result of the distance sensor is synchronized with the position data in the state where the toner is transferred to the transfer belt. A second storage means for storing is provided, and a thickness calculation means for calculating the thickness of the toner transferred to the transfer belt according to the position data from the two measurement results stored in the first storage means and the second storage means is provided. As a result, the toner print density can be measured by the transferred thickness, so that the toner print density can be satisfactorily measured from high density to low density. The thickness of the printing paper is measured with the thickness of the printing paper, but since the thickness of this printing paper is also measured separately and the position is synchronized and subtracted, the effects of printing paper thickness error and curvature are eliminated. The thickness of the toner can be measured with good accuracy.

According to the second aspect of the present invention, one distance sensor is arranged at a position facing the outer surface of the transfer belt, and position detecting means for detecting the circulating position of the transfer belt as position data is provided. First storage means is provided for storing the measurement result of the distance sensor in synchronization with the position data in a state where the toner is not transferred, and storing the measurement result of the distance sensor in synchronization with the position data in a state where the toner is transferred to the transfer belt. By providing the two storage means, the thickness calculation means for calculating the thickness of the toner transferred to the transfer belt according to the position data from the two measurement results stored in the first storage means and the second storage means. Since the toner print density can be measured by the transferred thickness, the toner print density can be satisfactorily measured from high density to low density. The thickness of the printing paper is measured together with the thickness of the printing paper, but since the thickness of this printing paper is also measured separately and the position is synchronized and subtracted, the influence of the printing paper thickness error and curving is eliminated. The thickness of the toner can be measured with good accuracy.

According to the third aspect of the present invention, the first distance sensor is arranged to face the outer surface of the transfer belt at a position where the toner is not transferred, and the second distance sensor is arranged to face the outer surface of the transfer belt where the toner is transferred. A position detecting means for detecting the circulating position of the transfer belt as position data is provided, and the measurement results of the first distance sensor and the second distance sensor are stored in synchronization with the position data in a state where the toner is not transferred to the transfer belt. First storage means is provided, and second storage means is provided for storing the measurement results of the first distance sensor and the second distance sensor in synchronization with the position data in a state where the toner is transferred to the transfer belt. By providing the thickness calculation means for calculating the thickness of the toner transferred onto the transfer belt according to the position data from the two measurement results stored in the second storage means and the second storage means, Since the density can be measured by the transferred thickness, the printing density of the toner can be satisfactorily measured from high density to low density, and the thickness of the toner is measured together with the thickness of the printing paper. Since the thickness of this printing paper is also measured separately and the position is synchronized and subtracted, it is possible to measure the thickness of the toner with good accuracy by eliminating the influence of errors and curvature of the printing paper. it can.

According to the fourth aspect of the present invention, the distance sensor is arranged so as to face the transfer belt at a position on the support roller, and therefore the distance sensor measures in a state where the transfer belt is properly held by the support roller. The accuracy can be improved.

According to the fifth aspect of the present invention, a large number of through holes are continuously formed in the conveyor belt, two distance sensors are arranged at positions facing each other through these through holes, and the conveyor belt conveys the distance. First storage means is provided for storing the measurement result of the distance sensor for the portion of the printing paper on which the toner is not transferred, and the first storage means for storing the measurement result of the distance sensor for the portion of the printing paper conveyed by the conveyor belt on which the toner is transferred By providing the two storage means and the thickness calculation means for calculating the thickness of the toner transferred to the printing paper from the two measurement results stored in the first storage means and the second storage means, Since the print density can be measured by the transferred thickness, the print density of toner can be satisfactorily measured from high density to low density, and moreover, the thickness of toner can be measured together with the thickness of printing paper. Although measurement, since the subtracted separately measured also the thickness of the printing paper, it is possible to measure the thickness of the toner with good accuracy.

According to a sixth aspect of the present invention, the conveyor belt is formed of a pair of endless belts arranged in parallel with a gap, and two distance sensors are arranged at positions opposed to each other with a gap between these endless belts. Then, the first storage means for storing the measurement result of the distance sensor for the portion of the printing paper conveyed by the conveyor belt to which the toner is not transferred is provided, and the distance sensor for the portion of the printing paper conveyed by the conveyor belt on which the toner is transferred And a thickness calculation unit that calculates the thickness of the toner transferred to the printing paper from the two measurement results stored in the first storage unit and the second storage unit. By providing the toner, the print density of the toner can be measured by the transferred thickness, so that the print density of the toner can be satisfactorily measured from high density to low density. Moreover, although measures the thickness of the toner with the thickness of the printing paper, since the subtracted separately measured also the thickness of the printing paper, it is possible to measure the thickness of the toner with good accuracy.

According to the seventh aspect of the present invention, since the two distance sensors measure the same position by providing the measurement control means for simultaneously sampling the two distance sensors, the measurement accuracy is improved. be able to.

According to the eighth aspect of the present invention, since the measurement control means for alternating the sampling timings of the two distance sensors is provided, mutual interference of the two distance sensors can be prevented. The accuracy can be improved.

According to the ninth aspect of the present invention, by providing the operation control means for stopping the operation of the movable part set in advance at the time of measuring the two distance sensors, the vibration of the movable part improves the measurement accuracy of the distance sensor. It can be prevented from lowering.

[Brief description of drawings]

FIG. 1 is a schematic view showing a digital copying machine which is a first embodiment of an electrophotographic apparatus of the present invention.

FIG. 2 is a perspective view showing a positional relationship between a transfer belt and a laser displacement meter that is a distance sensor.

FIG. 3 is a block diagram showing a circuit structure of a digital copying machine.

FIG. 4 is a flowchart showing a toner thickness detection operation.

5A and 5B show a relationship between a test pattern and a detection result of a laser displacement meter, FIG. 5A is a characteristic diagram showing a detection result of a laser displacement meter, and FIG. 5B shows a state in which a test pattern is formed on a transfer belt. It is a perspective view shown.

FIG. 6 is a flowchart showing a first modification of the toner thickness detection operation.

FIG. 7 is a flowchart showing a second modified example of the toner thickness detection operation.

FIG. 8 is a flowchart showing a third modified example of the toner thickness detection operation.

FIG. 9 is a perspective view showing a positional relationship between a transfer belt and a laser displacement meter according to a second embodiment.

FIG. 10 is a flowchart showing a toner thickness detection operation.

FIG. 11 is a flowchart showing a modified example of the toner thickness detection operation.

FIG. 12 is a perspective view showing a positional relationship between a transfer belt and a laser displacement meter according to a third embodiment.

FIG. 13 is a flowchart showing a toner thickness detection operation.

FIG. 14 is a flowchart showing a modified example of the toner thickness detection operation.

FIG. 15 is a schematic diagram showing a digital copying machine according to a fourth embodiment.

FIG. 16 is a perspective view showing a positional relationship between a conveyor belt and a laser displacement meter.

FIG. 17 is a schematic diagram showing a positional relationship among a transport belt, printing paper, and a laser displacement meter.

FIG. 18 is a flowchart showing a toner thickness detection operation.

FIG. 19 shows the relationship between the test pattern and the detection result of the laser displacement meter, (a) is a characteristic diagram showing the detection result of the laser displacement meter, and (b) shows the state in which the test pattern is formed on the printing paper. It is a perspective view shown.

FIG. 20 is a flowchart showing a modified example of the toner thickness detection operation.

FIG. 21 is a perspective view showing a positional relationship between a belt and a laser type displacement gauge according to a fifth embodiment.

[Explanation of symbols]

 1,44 Electrophotographic device 6 Exposure device 7 Photoconductor 10 Charging device 12 Developing device 14 Transfer belt 15 Support roller 21 Paper transport mechanism 24 Fixing device 27, 28, 47, 48 Distance sensor 39 Toner 41 Printing paper 45, 54 Transport belt 46 through hole 51 gap 52, 53 endless belt

Claims (9)

[Claims] 1. A surface of a photoconductor is uniformly charged by discharge of a charging device, and the surface of the charged photoconductor is selectively discharged by exposure of an exposing device to form an electrostatic latent image. The electrostatic latent image is developed with the toner supplied from the developing device, the toner is transferred to an endless transfer belt stretched by a plurality of supporting rollers in a circulating manner, and the toner attached to the transfer belt is transferred by a paper transport mechanism. In an electrophotographic apparatus in which toner is transferred to a print sheet that is conveyed and the toner transferred to the print sheet is fixed by a fixing device, two distance sensors are arranged at positions facing each other through the transfer belt, and the transfer belt is provided. A position detecting means for detecting the circulating position of the distance sensor as position data, and stores the measurement result of the distance sensor in synchronization with the position data in a state where toner is not transferred to the transfer belt. A storage means is provided, and a second storage means is provided for storing the measurement result of the distance sensor in synchronization with the position data in a state where the toner is transferred to the transfer belt,
A thickness calculating means for calculating the thickness of the toner transferred to the transfer belt according to position data from the two measurement results stored in the first storage means and the second storage means is provided. Electrophotographic device. 2. The surface of the photoconductor is uniformly charged by the discharge of a charging device, and the charged surface of the photoconductor is selectively discharged by the exposure of an exposing device to form an electrostatic latent image. An electrostatic latent image is developed with toner supplied from a developing device, this toner is transferred to an endless transfer belt stretched by a plurality of support rollers in a circulating manner, and the toner attached to this transfer belt is transferred by a paper transport mechanism. In an electrophotographic apparatus in which a toner is transferred onto a printing paper that is conveyed and the toner transferred onto the printing paper is fixed by a fixing device, one distance sensor is arranged at a position facing the outer surface of the transfer belt, Position detection means for detecting the circulation position as position data is provided, and the measurement result of the distance sensor is stored in synchronization with the position data in a state where toner is not transferred to the transfer belt. A storage means is provided, and a second storage means is provided for storing the measurement result of the distance sensor in synchronization with the position data in a state where the toner is transferred to the transfer belt,
A thickness calculating means for calculating the thickness of the toner transferred to the transfer belt according to position data from the two measurement results stored in the first storage means and the second storage means is provided. Electrophotographic device. 3. The surface of the photoconductor is uniformly charged by discharge of a charger, and the charged surface of the photoconductor is selectively discharged by exposure of an exposure device to form an electrostatic latent image. An electrostatic latent image is developed with toner supplied from a developing device, this toner is transferred to an endless transfer belt stretched by a plurality of support rollers in a circulating manner, and the toner attached to this transfer belt is transferred by a paper transport mechanism. In an electrophotographic apparatus in which toner is transferred to a printing paper to be conveyed, and the toner transferred to the printing paper is fixed by a fixing device, a first distance sensor is arranged to face the outer surface of the transfer belt at a position where the toner is not transferred, A second distance sensor is arranged opposite to a position on the outer surface of the transfer belt where the toner is transferred, and position detecting means for detecting the circulating position of the transfer belt as position data is provided. Is provided with a first storage unit for storing the measurement results of the first distance sensor and the second distance sensor in synchronization with the position data in a state where the toner is not transferred to the transfer belt. Two measurement results stored in the first storage means and the second storage means are provided with second storage means for storing the measurement results of the first distance sensor and the second distance sensor in synchronization with the position data. An electrophotographic apparatus comprising a thickness calculating means for calculating the thickness of the toner transferred to the transfer belt according to the position data from 4. The distance sensor is arranged at a position on the supporting roller so as to face the transfer belt.
The described electrophotographic apparatus. 5. The surface of the photoconductor is uniformly charged by discharge of a charging device, and the charged surface of the photoconductor is selectively discharged by exposure of an exposing device to form an electrostatic latent image. The electrostatic latent image is developed by the toner supplied from the developing device, and the printing paper is sequentially transported by the endless transport belt stretched by a plurality of supporting rollers in a circulating manner, and the toner developed on the printing paper transported. In the electrophotographic apparatus in which the toner transferred to the printing paper is fixed by the fixing device, a large number of through holes are continuously formed in the conveyor belt, and two through holes are formed at the positions opposite to each other. First distance storing means for arranging the distance sensors, storing the measurement result of the distance sensor with respect to the portion of the printing paper conveyed by the conveyor belt, on which the toner is not transferred, is conveyed by the conveyor belt. A second storage unit is provided for storing the measurement result of the distance sensor with respect to the portion of the printing paper on which the toner is transferred, and the printing paper is obtained from the two measurement results stored in the first storage unit and the second storage unit. An electrophotographic apparatus comprising a thickness calculating means for calculating the thickness of the transferred toner. 6. The surface of the photoconductor is uniformly charged by discharge of a charger, and the charged surface of the photoconductor is selectively discharged by exposure of an exposure device to form an electrostatic latent image. The electrostatic latent image is developed by the toner supplied from the developing device, and the printing paper is sequentially transported by the endless transport belt stretched by a plurality of supporting rollers in a circulating manner, and the toner developed on the printing paper transported. In an electrophotographic apparatus in which the toner transferred to the printing paper is fixed by a fixing device, the conveyor belt is formed by a pair of endless belts arranged side by side with a gap, and the gap between these endless belts is Two distance sensors are arranged at positions opposite to each other, and a measurement result of the distance sensor for a portion of the printing paper conveyed by the conveyor belt on which toner is not transferred is stored. A first storage means is provided, and a second storage means is provided for storing the measurement result of the distance sensor with respect to a portion of the printing paper conveyed by the conveyance belt on which the toner is transferred, and the first storage means and the second storage means are provided. An electrophotographic apparatus, comprising: a thickness calculation means for calculating the thickness of the toner transferred onto the printing paper from the two measurement results stored in and. 7. An electrophotographic apparatus according to claim 1, 3, 5 or 6, further comprising measurement control means for simultaneously sampling the two distance sensors at sampling timings. 8. The electrophotographic apparatus according to claim 1, 3, 5 or 6, further comprising measurement control means for alternating sampling timings of the two distance sensors. 9. The electrophotography according to claim 1, 2, 3, 5 or 6, further comprising operation control means for stopping the operation of a movable part set in advance when measuring the two distance sensors. apparatus.