JPH10333419A - Image forming device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To always keep the concentration of toner optimum in a developing means, irrespectively of the video count value of an image or a toner replenishing time by correcting the replenished toner amount while weighting the consumption of the toner required for the image in forming. SOLUTION: The video count value Vc corresponding to image information is calculated (S4), and the predicted toner replenishing time Tp corresponding to the calculated value Vc is obtained (S5). In the case the deviation of the toner concentration in a developing unit from the initial-set value is detected by a developer concentration measuring sensor, or by the toner concentration detection using a patched reference image (S8), it is judged by a CPU whether the replenished toner amount is too much or too little, then, judged whether the replenished toner amount for the video count value Vc is too much or too little, then, in order to correct the predicted toner replenishing time Tp for the video count value Vc, the part of the video count value Vc of a replenishment coefficient (f) and the part near the value Vc are rewritten so as to correct the replenished toner amount at the sequential stages (S9).

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a copying machine which employs an electrophotographic system or an electrostatic recording system in which a developer is attached to a latent image formed on an image carrier to visualize the latent image. The present invention relates to an image forming apparatus such as a printer.

[0002]

2. Description of the Related Art Generally, an image forming apparatus employing an image recording system such as an electrophotographic system or an electrostatic recording system generally includes:
A two-component developer mainly composed of toner particles and carrier particles is used. The toner concentration of the two-component developer (that is, the ratio of the weight of the toner particles to the total weight of the carrier particles and the toner particles) is a very important factor in stabilizing image quality. Since the toner particles of the developer are consumed during development, the toner concentration changes with time. For this reason, the toner concentration of the developer is accurately detected in a timely manner using a developer concentration control device, and toner is replenished in accordance with the change in the toner concentration to constantly control the toner concentration to maintain the image quality. There is a need to.

FIG. 6 shows a digital copying machine adopting an electrophotographic system as a conventional example of an image forming apparatus provided with a developer concentration control device.

In FIG. 1, a photosensitive drum 17 serving as an image carrier is irradiated with a laser beam, on which an electrostatic latent image corresponding to an image signal is formed. Then, this electrostatic latent image is developed by the developing device 20 and is visualized as a toner image.

The digital copying machine is provided with a video count type developer concentration control device for correcting the changed toner concentration in the developing device 20 as a developing means by developing the latent image. The toner is predicted and replenished by integrating the output level of the digital image signal for each pixel.

That is, an analog-to-digital converter (A /
The output level of each pixel is added to the image signal converted into a digital signal by the D converter 3, and the integrated signal is converted into a video count number by a video count 4 and sent to the CPU 6. The CPU 6 converts the video count into a toner supply amount, and sends this to the motor drive circuit 7 as a toner supply signal. The motor drive circuit 7 drives the motor 28 for a time corresponding to the toner replenishment signal, and rotates and drives the toner transport screw 30 in the toner replenishment tank 8 serving as a toner storage unit for storing the toner 29 for the predetermined time. Vessel 8
An appropriate amount of toner is supplied to the developing device 20 and the developing device 20
Is kept constant.

As described above, in the above-described conventional developer concentration control device, the toner replenishment amount is converted from the video count number obtained by integrating the output level of each pixel of the digital image signal. For example, the toner supply time is converted into the toner supply time, and the toner supply amount is supplied from the toner supply tank 8 to the developing device 20, for example, is deviated from the estimated value due to a change in toner fluidity. Then, the toner concentration in the developer in the developing device 20 deviates from the initial set value.

A second developer concentration control device and a third developer concentration control device are provided for the purpose of correcting the deviation of the toner concentration of the developer, and the first developer concentration control of the video count method is provided. It has been proposed for use with the device.

The second developer concentration control device includes a developing device 20
The toner concentration in the two-component developer is detected by a toner concentration sensor 21 installed in the inside. The third developer density controller operates at a predetermined timing to form a patch-like reference image on the photosensitive drum 17 by a known means, and optically detects the density of the reference image on the patch by an optical detecting means 22. To detect.

Based on these detection results, it is determined whether the toner is oversupplied or undersupplied. Based on the judgment, the next video count from the video counter 4 is corrected, and the toner replenishment from the CPU 6 is performed. By correcting the signal, the deviation of the toner density from the initial set value by the first developer density control device of the video count system is corrected.

Further, in order to prevent a deviation of the toner supply amount, a learning type toner supply amount correction device for uniformly correcting a supply table or a supply function for converting the toner supply amount based on the video count into a toner supply time is proposed. Have been.

This is because when the toner replenishment amount based on the video count value is X, the replenishment function which is a function of X is f, and the toner replenishment time is t = f (X), the target value D of the toner density is obtained.
_In contrast, if the toner density after the image forming process is D, the toner supply amount is corrected by rewriting the supply function to, for example, (D ₀ / D) f (X) → f (X). , To prevent the toner density from fluctuating in the subsequent image forming process.

[0013]

However, the second developer concentration control device and the third developer concentration control device include:
Each has the following problems.

The toner concentration sensor 21 used in the second developer concentration control device is provided at the most downstream portion of the developer circulation in the developing device 20. This is because, if provided on the upstream side, a change in the toner density cannot be detected when the toner of the developer is consumed on the downstream side of the density sensor.

Further, when the toner is consumed, an appropriate amount of the toner is replenished into the developing device 20. The replenished toner is sufficiently mixed and stirred with the existing developer, and a sufficient tribo is provided. Therefore, it is subjected to development via a long stirring and conveying path. For this reason, there is a time lag until the recovery of the toner concentration in the developing chamber is detected after the consumption of the toner, and the toner concentration cannot be controlled.

In the third developer concentration control device, the patch-like reference image may not be formed during the continuous image forming process, and the toner concentration may not be controlled.

In these cases, the control of the toner density depends on the accuracy of the predicted replenishment by the video count method.

However, what is controlled based on the video count value is the replenishment time (driving time of the toner hopper) and not the toner replenishment amount itself.
It is necessary to improve the accuracy of a replenishment table or a replenishment function for converting a video count value into a toner replenishment time.

Therefore, it is considered effective to correct the replenishment table or the replenishment function by the learning type toner replenishment amount correction device.

However, since the learning type toner replenishing amount correcting device uniformly corrects the replenishing table or the replenishing function, the toner replenishing capacity of the toner hopper (the toner replenishing amount per unit driving time of the toner hopper) is reduced. The toner replenishment amount cannot be accurately corrected unless it is constant regardless of the toner replenishment time (toner hopper driving time).

Actually, the replenishing ability of the toner hopper varies depending on the toner replenishing time due to a change in toner fluidity due to a difference in the toner hopper driving time and an influence of a backlash of the toner hopper driving system. for that reason,
After uniformly correcting the replenishment table or replenishment function based on the toner density change of the two-component developer in the image forming process of a certain video count value, the toner density greatly changes when an image of a different video count value is formed. May be done.

Accordingly, it is an object of the present invention to provide an image forming apparatus capable of always maintaining an appropriate toner density in a developing unit regardless of a video count value of an image or a toner replenishing time. .

[0023]

The above object is achieved by an image forming apparatus according to the present invention. In summary, the present invention provides:
In an image forming apparatus having a developing unit for developing an electrostatic latent image formed on an image carrier with toner, and a toner storage unit for storing toner for replenishing toner to the developing unit, An image forming apparatus is characterized in that a toner replenishment amount from a toner storage unit to the developing unit is corrected while weighting is performed by a toner consumption amount of an image being formed. 2. The image forming apparatus according to claim 1, wherein the correction of the toner supply amount is performed during normal image formation to improve toner supply accuracy.

The above-described correction of the toner replenishment amount is performed at times other than the normal image formation, and an optimum toner replenishment amount can be obtained by one correction regardless of the toner consumption amount of the image to be formed.
The correction of the toner replenishment amount is performed by converting a video replenishment function or a toner replenishment table for converting a video count value of the image into a toner replenishment amount based on a change in toner density in the two-component developer during image formation. It is preferable to perform the correction by correcting only the video count value and its vicinity.

According to another aspect, the correction of the toner replenishment amount is performed by using the toner replenishment function or the toner replenishment table.
Based on the change in toner density in the two-component developer during image formation, all video count values are uniformly corrected, and the video count value of an image being formed and its vicinity are corrected. Is preferred.

According to still another aspect, the toner replenishment amount is corrected by forming a plurality of types of reference images having different video count values, and changing the toner density in the two-component developer during the formation of each reference image. Preferably, the correction is performed by correcting the supply function or the toner supply table based on

Preferably, the correction of the toner supply amount is performed by changing the toner supply time. It is preferable that the contents of the correction of the toner replenishment amount be stored and the correction be performed also in the subsequent image formation.

[0028]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an image forming apparatus according to the present invention will be described in more detail with reference to the drawings. An image forming apparatus to which the present invention can be applied, for example, forms an electrostatic latent image on an image carrier such as a photoreceptor or a dielectric by an electrophotographic method, an electrostatic recording method, or the like. A visible image (toner image) is formed by developing with a developing device using a two-component developer containing particles and carrier particles as main components, and the visible image is transferred to a transfer material such as paper, and permanently fixed by a fixing unit. What is necessary is just a thing of the composition which turns into an image.

Embodiment 1 First, an overall configuration of Embodiment 1 of an image forming apparatus according to the present invention will be described with reference to FIG. The same members as those described above are denoted by the same reference numerals.

In FIG. 1, an image of an original 11 is a CCD 1
2, an analog image signal obtained is amplified to a predetermined level by an amplifier 13, and an analog-digital converter (A / D converter) 3 outputs, for example, 8 bits (0/0).
(Up to 255 gradations). Next, this digital image signal is supplied to a gamma converter 14, where it is subjected to gamma correction, and then input to a digital-analog converter (D / A converter) 15.

The converter 15 converts the digital image signal into an analog image signal again.
Is supplied to one of the inputs. The other input of the comparator 16 is supplied with a triangular wave signal of a predetermined cycle generated from the triangular wave generating circuit 17.
The analog image signal supplied to one input is compared with the triangular wave and pulse width modulated. The pulse width modulated binarized image signal is directly input to the laser drive circuit 18 and used as an on / off control signal for light emission of the laser diode 19. The laser beam emitted from the laser diode 19 is scanned in the main scanning direction by a well-known polygon mirror 31, passes through an f / θ lens 32, and a reflection mirror 33, and rotates as indicated by an arrow in the direction of the arrow. 17 to form an electrostatic latent image.

On the other hand, the photosensitive drum 17 is uniformly discharged by the exposure device 40 and is uniformly charged, for example, negatively by the primary charger 41. Thereafter, an electrostatic latent image corresponding to the image signal is formed by receiving the above-described laser light irradiation. A toner replenishing tank 8, which is a toner storage unit for storing replenishing toner 29, is mounted above the developing device 20.
A toner conveying screw 30 that conveys the toner 29 by being rotationally driven by the motor 28 and supplies the toner 29 to the inside of the developing device 20 is installed in a lower part of the inside.

The toner image formed on the photosensitive drum 40 is transferred by a transfer charger 54 onto a transfer material 55 conveyed to the photosensitive drum 17 by a transfer material carrying belt 53. The transfer material carrying belt 53 includes two rollers 51,
The transfer material 55 is stretched between the rollers 52 and driven endlessly in the direction of the arrow in the figure to convey the transfer material 55 held thereon to the photosensitive drum 17. The transfer residual toner remaining on the photosensitive drum 17 is thereafter scraped off by the cleaner 50.

For simplicity of explanation, only a single image forming station (including the photosensitive drum 17, the exposing unit 40, the primary charging unit 41, the developing unit 20 and the like) is shown.
In the case of a color image forming apparatus, for example, image forming stations for cyan, magenta, yellow, and black are sequentially arranged on the transfer material carrying belt 53 along the moving direction thereof.

As described above, the image signal converted into a digital signal by the analog-to-digital converter (A / D converter) 3 has its output level integrated for each pixel. It is converted into a count and sent to the CPU 6. The CPU 6 converts the video count into a toner supply amount, and sends this to the motor drive circuit 7 as a toner supply signal. The motor drive circuit 7 drives the motor 28 for a time corresponding to the toner replenishment signal, and rotates and drives the toner transport screw 30 in the toner replenishment tank 8 containing the toner 29 for the predetermined time.
An appropriate amount of toner is supplied to the developing device 20 and the developing device 20
Is kept constant.

As described above, after the development of the latent image,
When the toner is replenished, the toner replenishment amount is controlled by the above-described video count type developer concentration control device. This is predictive replenishment by converting the video count value obtained by integrating the output level of each pixel of the digital image signal into a toner replenishment time by a toner replenishment function, and driving the toner conveying screw 30 by the motor 28 for the replenishment time. .

Since the toner replenishment amount due to the predicted replenishment causes an error as described above and the toner concentration in the developer deviates from the initial set value, the second and third developer concentration control devices are provided. , And is used in combination with the above-mentioned video count type developer concentration control device.

In the second developer concentration control device, the developing device 2
An optical type developer density sensor 21 is provided in 0 to detect the toner density in the two-component developer. Further, the third developer concentration control device operates at a predetermined timing to form a patch-like reference image on the photosensitive drum 17, and the toner density of the patch-like reference image is detected by the optical detection unit 22. Detected.

These toner density detection signals are sent to the CPU 6
The CPU 6 determines whether the toner supply amount is excessive or insufficient based on the video count value based on the detection signal, corrects the toner supply time, and corrects the deviation of the toner density from the initial set value.

However, as described above, these second and third
Correction of the toner concentration by the developer concentration control device may not be performed. Therefore, in the present embodiment, the accuracy of the video count type developer concentration control device is increased and the deviation of the toner concentration from the initial set value is prevented by the method described in detail below.

FIG. 2 is a flowchart showing the flow of this correction method.

When the number N of copies is input (Step 1, hereinafter referred to as S1) and the continuous copying process is started (S2), the number I of counters is set to 1 (S1).
3), the video count value V _C corresponding to the image information is calculated (S4), the prediction replenishing time of toner corresponding T
_p is obtained (S5). At this time, the relationship between the video count value V _c and the predicted supply time T _p, using the toner replenishing function f, denoted _{T P = f (V c)} .

When an image is formed (S6), the toner conveying screw 30 is driven only for the estimated replenishment time T _P ,
The toner is supplied to the developing device 20 (S7).

Incidentally, the detection of the toner density in the developing device 20 by the above-described second developer density measuring device is performed for each copy operation. Further, the toner density detection using the patch-like reference image by the third developer density measuring device is performed at every fixed number of sheets during the continuous copy operation, for example, at every 100 sheets, and at the end of the continuous copy.

[0045] performed number of sheets that a copy operation, by which the toner supply is repeated by the prediction replenishment time T _P of the toner based on the video count value V _c, the developing device 20
When a deviation of the toner density from the initial setting value into the toner density detection sensor 21 in the developing device 20 is detected,
Alternatively, when the toner replenishment function f is corrected by adding a correction to the toner replenishment function f when the toner replenishment function f is detected by detecting the toner density using the patch-like reference image at a constant width during the continuous copy operation and at the end of the continuous copy (S8). _p is corrected, and the toner supply amount thereafter is corrected (S9).

If the deviation of the toner density in the developing unit 20 from the initial set value can be detected from the first copy operation, the toner supply amount is corrected by the above method from the second copy operation. Is done.

The correction of the toner supply function f is shown in FIGS.
This is performed as shown in FIG. First, in the image formation with the video count value V _C1 , as a result of toner replenishment for the replenishment time T _P1 obtained from the initial replenishment function f ₀ (FIG. 3A), the toner density D becomes the initial D _0. From D ₁
(FIG. 3B). When the density detection signal is sent to the CPU 6, CPU 6 determines the excess or deficiency of the toner supply amount, determines excess and deficiency of the toner supply amount in the video count value V _C1, the toner supply time in the video count value V _C1 T _P1 To compensate for
The portion of the replenishment function f ₀ where V _C = V _C1 and its vicinity are rewritten.

The supply function corrected in this way is represented by f ₁
(FIG. 3C). If the correction of the replenishment function is performed during the continuous copy operation, the corrected replenishment function is performed immediately after the next image formation, and when the correction is performed at the end of the copy, from the start of the next copy. prediction replenishment time T _p using the f ₁ is required.

With this correction, when continuous copying is continued, or when a new copy of an image whose video count value V _C is _close to V _C1 is newly started, the accuracy of the developer concentration control device of the video count system is increased. Improve,
Variations in the toner concentration of the developer can be prevented.

Subsequently, when an image having a video count value of V _C2 is formed after the supply function is rewritten to f ₁ , the supply time T _P2 obtained from the supply function f ₁ is used in the same manner as described above. As a result of toner supply (FIG. 3
(D)), the toner density D is to be changed from the initial concentration D ₀ to D ₂ is detected (FIG. 3 (e)). The density detection signal is sent to the CPU 6, it is determined that excess and deficiency of the toner supply amount, determines excess and deficiency of the toner supply amount in the video count value V _C2, correct toner replenishment time T _P2 in the video count value V _C1 In this case, the portion where V _C = V _C2 and its vicinity are rewritten (FIG. 3F).

[0051] In this way, by repeating the formation of the video count value V _C of different images, the correction of the supply function, supply function f _n is obtained (FIG. 3 (g)).

Since the replenishment function f _n is obtained based on the toner density change at the time of actual image formation, it is optimal for image formation of any video count value regardless of the replenishment capability characteristics of the toner hopper alone. The toner supply amount can be obtained.

Further, even when the flow characteristics of the toner change due to the change of the use environment or the durability, that is, the change of the replenishing ability characteristic of the toner hopper due to long-term use, the correction of the replenishment function is repeated. As a result, it is possible to always maintain the toner concentration of the two-component developer in an allowable range.

Second Embodiment Next, a second embodiment of the present invention will be described with reference to FIG.
In the present embodiment, in addition to the correction of the video count value of the image being formed and the replenishment function in the vicinity thereof in the first embodiment, a uniform replenishment function is performed regardless of the video count.

A factor that greatly affects the replenishing ability of the toner hopper is the fluidity of the toner. The fluidity of the toner is closely related to the bulk density of the toner. As the properties, the higher the bulk density, the lower the fluidity and conversely, the more the replenishing ability. In particular, immediately after toner is replenished to the toner hopper, a large amount of toner having low bulk density and high fluidity is replenished, thereby increasing the replenishing ability of the toner hopper. Further, the fluidity of the toner also changes depending on the use environment such as temperature and humidity, and affects the replenishing ability of the toner hopper.

Such a change in the replenishing ability of the toner hopper due to a change in the fluidity of the toner causes an error in the toner replenishing amount regardless of the video count value of the image being formed. Therefore, in the present embodiment, as shown in FIGS. 4A to 4C, in addition to the video count value of the image being formed and its vicinity, the correction of the toner replenishment function is uniform regardless of the video count value. Are doing.

As described in the first embodiment, first, in the image formation with the video count value of V _C1 , the result of toner replenishment for the replenishment time T _P1 obtained from the initial replenishment function f ₀ (FIG. 4 (a)), the toner density D is the initial D
₀ and it was changed to D ₁ is detected (FIG. 4
(B)). When this density detection signal is sent to the CPU 6,
CPU6 determines the excess or deficiency of the toner supply amount, determines excess and deficiency of the toner supply amount in the video count value V _C1, in order to correct the toner replenishment time T _P1 in the video count value V _C1, the replenishment function f ₀ Rewrite the portion of V _C = V _C1 and its vicinity. Further, the supply function is changed from the dotted line L to the solid line L
₁ to obtain a replenishment function f ₁ (FIG. 4
(C)).

By repeating the correction of the toner replenishment function by this method, a toner replenishment function corresponding to the replenishment capability characteristic of the toner hopper can be obtained, and a change in the toner replenishment capability of the toner hopper due to a change in the fluidity of the toner is obtained. Can be corrected with a smaller number of corrections.

Third Embodiment Next, a third embodiment of the present invention will be described with reference to FIG.
In the present embodiment, a plurality of types of reference images having different video count values are formed for each required number of images, and the toner replenishment function is corrected based on the change in the toner concentration in the two-component developer during the formation of each reference image. This is performed simultaneously for all video count values. FIG. 5 shows the correction procedure.

In this embodiment, as shown in FIG.
Video count value V _C1 from low density image to high density image
The formation of n types of reference images having different .about.V _Cn is performed.
Estimated toner supply time _{TP1 for} each reference image formation
T _Pn is obtained by an initial toner supply function f ₀ .
Further, each reference image has a sufficient number of toner images or a patch-like reference image in which the deviation of the toner density in the developing device 20 from the initial setting value is detected by the developer density measuring sensor 21 in the developing device 20. Are formed by the number of sheets sufficient to be detected by the toner density detecting means 22 using
When change D ₁ to D _n of the toner density by the reference image forming respective video count value is detected (Fig. 5
(B)) Based on the result, the toner replenishment function f ₀ is simultaneously performed for all video count values.
_It is corrected as _n (FIG. 5C).

According to the present embodiment, since a reference image having a different video count value is formed in advance and a change in toner density is detected, the user is not required to output images having various video count values. , All video count values are corrected. Therefore, a replenishment function corresponding to the replenishing ability characteristic of the toner hopper can be obtained by one correction, and an optimal toner replenishment amount can be obtained regardless of the video count value of the output image.

[0062]

As is apparent from the above description, according to the present invention, the amount of toner supplied from the toner storage means to the developing means in the image forming process is weighted by the amount of toner consumed for the image being formed. By correcting while
Regardless of the video count value of the image or the toner replenishment time, the toner density in the developing unit can always be maintained at an appropriate value, and a high-quality image can always be obtained.

[Brief description of the drawings]

FIG. 1 is a configuration diagram illustrating an embodiment of an image forming apparatus according to the present invention.

FIG. 2 is a flowchart showing a procedure for correcting a toner supply amount according to the present invention.

FIG. 3 is a diagram illustrating a procedure for correcting a toner supply function f according to the first embodiment.

FIG. 4 is a diagram illustrating a procedure for correcting a toner supply function f according to the second embodiment.

FIG. 5 is a diagram illustrating a procedure for correcting a toner supply function f according to a third embodiment.

FIG. 6 is a configuration diagram illustrating an example of a conventional image forming apparatus (digital copying machine).

[Explanation of symbols]

4 Counter 6 CPU 8 Toner Replenishing Tank (Toner Storage Unit) 17 Photosensitive Drum (Image Carrier) 20 Developing Unit (Developing Unit) 21 Toner Density Sensor in Developing Unit (Second Developer Density Control Device) 22 Patch Density Optical Detection means (third
Developer concentration control device)

Claims (8)

[Claims] 1. An image forming apparatus comprising: developing means for developing an electrostatic latent image formed on an image carrier with toner; and toner storing means for storing toner for supplying toner to the developing means. An image forming apparatus, wherein a toner supply amount from the toner storage unit to the developing unit in an image forming process is corrected while weighting the toner supply amount of the image being formed. 2. The image forming apparatus according to claim 1, wherein the correction of the toner supply amount is performed during normal image formation to improve toner supply accuracy. 3. The method according to claim 1, wherein the correction of the toner replenishment amount is performed other than during normal image formation, and one correction makes it possible to obtain an optimum toner replenishment amount regardless of the toner consumption amount of an image to be formed. The image forming apparatus according to claim 1, wherein: 4. The method according to claim 1, wherein the toner replenishment amount is corrected by using a toner replenishment function or a toner replenishment table for converting a video count value of an image into a toner replenishment amount based on a toner density change in a two-component developer during image formation. 3. The image forming apparatus according to claim 2, wherein the correction is performed by correcting only a video count value of an image being formed and a portion near the video count value. 5. The correction of the toner replenishment amount is such that the video replenishment function or the toner replenishment table uniformly corrects all video count values based on a change in toner density in a two-component developer during image formation. 3. The image forming apparatus according to claim 2, wherein the correction is performed by correcting the video count value of the image being formed and the vicinity thereof. 6. The replenishment function according to claim 1, wherein a plurality of types of reference images having different video count values are formed, and the toner supply amount is corrected based on a change in toner density in a two-component developer during the formation of each reference image. 4. The image forming apparatus according to claim 3, wherein the correction is performed by correcting a toner supply table. 7. The image forming apparatus according to claim 1, wherein the correction of the toner supply amount is performed by changing a toner supply time. 8. A correction content of the toner supply amount is stored,
The image forming apparatus according to claim 1, wherein the correction is performed also when the image is formed thereafter.