KR0148513B1 - Correction method and device of depreciation drum of electronic copier - Google Patents

Abstract

The present invention relates to a method and a device for correcting the photosensitive drum aging of an electronic copying machine which automatically detects and corrects a change in the radiation image density according to the aging of the photosensitive drum of the electronic copying machine. A toner pattern is temporarily formed on the substrate, the density of the toner pattern is detected and compared with a reference value, and when the density detection value is smaller than the reference value, the screen grid voltage is automatically corrected in the direction of increasing the screen grid voltage, thereby adjusting the photosensitive drum. When the density detection value is higher than the reference value, the screen grid voltage is automatically corrected in the direction of lowering the screen grid voltage, thereby automatically reducing the degradation of the radiation image quality due to the aging of the photosensitive drum. Will be compensated.

Description

Degradation method and device of photosensitive drum aging of electronic copying machine

The present invention relates to the correction of photosensitive drum aging of an electronic copying machine, and more particularly, to a photosensitive drum aging correction method and apparatus for an electronic copying machine which automatically detects and corrects a change in the radiation image density according to the aging of the photosensitive drum of the electronic copying machine. It is about.

In general, the electromagnetic copy machine changes the radiation image density due to the aging of the photosensitive drum and the contamination of the optical system, and the variation of other adjustment units.

At this time, since the copy image density changes to a side that is worse than the optimum state, the actual copy operation deteriorates the copy state, that is, the image quality state.

Since the conventional electronic copier does not have a function of detecting and correcting the change of the copy image density as described above, it is impossible to automatically correct it.

Therefore, when the copy image density is changed due to the aging of the photosensitive drum and the contamination of the optical system or other adjustment part, the image quality is degraded by the user. In this case, the old part of the photosensitive drum was corrected or the variation of other adjusting parts was corrected by directly adjusting the corresponding part.

However, this correction method has a disadvantage in that it is inconvenient because the user directly corrects the radiation image density when the photosensitive drum is deteriorated and the optical contamination or other control unit changes.

In addition, in the case of a user who does not handle the electronic copier professionally, there is a disadvantage that it is very difficult to correct the decrease in the copy image density as described above.

Accordingly, the present invention has been proposed to solve various problems occurring when the photoconductor drum aging of the conventional electronic copying machine is corrected, and the present invention automatically changes the radiation image density that changes according to the aging of the photosensitive drum of the electronic copying machine. It is an object of the present invention to provide a method and a device for correcting the photosensitive drum aging of an electronic copying machine that detects and corrects it.

According to the present invention for achieving the above object, three toner patterns are arbitrarily formed on the photoconductive drum, and the density of the formed toner pattern is detected by a density detection sensor, and then the detected detection value and the copy image density To determine the change, compare the reference values set in advance as a reference, and determine whether or not there is a change in the copy image density, and if the copy image density is changed, adjust the screen grid voltage by the change to change the copy image density. It is characterized by automatically correcting.

1 is a schematic configuration diagram of an electromagnetic copying machine of the indirect electrostatic brush development method to which the present invention is applied.

2 is a block diagram of a photosensitive drum deterioration correcting device of an electronic copying machine according to the present invention.

3 is an explanatory diagram for explaining a toner pattern formed on the photosensitive drum in the present invention.

4 is a flowchart illustrating a process of forming and removing a toner pattern in the present invention.

5 is a flowchart illustrating a method for correcting the photosensitive drum aging of the electromagnetic copying machine according to the present invention.

* Explanation of symbols for main parts of the drawings

2: screen grid 3: photosensitive drum

9 concentration sensor 10 central processing unit

11: screen and voltage converter 12: toner pattern

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a schematic configuration diagram of an electromagnetic copying machine of the indirect electrostatic brush development method to which the present invention is applied.

Here, reference numeral 1 denotes a corona discharge when a high DC voltage of several KV is applied to generate a charging current, and to charge the surface of the photosensitive drum 3 by varying the charging current according to the voltage applied to the screen grid 2. It is a charge charger, reference numeral 4 denotes a blank lamp for selectively erasing the charged charge of the photosensitive drum 3, and reference numeral 5 denotes a developer for developing only the toner pattern remaining on the photosensitive drum 3.

Further, reference numeral 6 denotes a transfer / separation charger for transferring the image of the toner formed on the surface of the photosensitive drum 3 to copy paper and separating the copy paper from the photosensitive drum 3, and reference numeral 7 denotes the photosensitive drum. An antistatic lamp for removing all of the deterioration remaining on the surface of (3), and reference numeral 8 is a cleaning device for removing residual toner on the surface of the photosensitive drum (3).

The electromagnetic copy machine having the above configuration is a general indirect electromagnet brush developing type electronic copy machine, and the present invention is mounted at a predetermined position (position close to the photosensitive drum) of the general electromagnetic copy machine as described above, so that the surface of the photosensitive drum 3 Further comprising a density detection sensor (9) consisting of a light emitting element and a light receiving element for detecting the concentration of the toner pattern formed in the to realize an electronic copying machine.

2 is a block diagram of a photosensitive drum aging compensator for an electronic copying machine according to the present invention.

As shown therein, the density detecting sensor 9 detects the density of the toner pattern formed on the surface of the photosensitive drum 3, the density value of the toner pattern detected by the density detecting sensor 9 and the photosensitive drum aging. In order to determine whether the photosensitive drum is deteriorated according to the result of the comparison, a predetermined reference value is determined in order to determine whether to change the voltage of the screen grid 2, and if it is determined that the photosensitive drum is old, the voltage of the screen grid 2 is determined. A central processing unit (10) for generating a control signal for changing, a screen grid voltage converting unit (11) for changing a voltage of the screen grid (2) in accordance with a control signal output from the central processing unit (10), and And a toner pattern 12 formed by the blank lamp 4 and the developer 5.

3 is a view showing a toner pattern 12 formed on the surface of the photosensitive drum 3 by the photosensitive drum aging compensator according to the present invention as described above.

The operation of the photosensitive drum aging correction apparatus according to the present invention configured as described above and the photosensitive drum aging correction method according to the present invention will be described in detail with reference to FIGS. 1 to 5 as follows.

First, the electronic copy manufacturer stores a reference value for determining whether the photosensitive drum is deteriorated in a memory device (not shown) in the electronic copy machine and then ships the product. The method for calculating the reference value is briefly described. Is as follows.

First, assuming that the voltage applied to the screen grid 2 in the standard state is Vg (p) (the voltage applied to the screen grid in the standard state), this Vg (p) is applied to the screen grid 2, and the standard of the electromagnetic copy machine is applied. A square toner pattern 12 is formed on the photosensitive drum 3 in the adjusted state (new photosensitive drum is new) as shown in FIG.

The method of forming the toner pattern 12 will be described later in detail.

On the other hand, after forming the toner pattern 12 as described above, the light emitting element constituting the density detection sensor 9 is irradiated with light to the toner pattern 12, and the reflected light is read by the light receiving element and the output value is referred to as a reference value. To the storage device.

The reference value may vary depending on the sensitivity of the photosensitive drum, the constant of each device, the magnitude of the charging current, the toner concentration in the developing device, and the like. After that, the average value is set as the reference value.

On the other hand, when a reference value is stored in the storage device as described above, when the electronic copy machine is shipped, and a user who purchases the shipped electronic copy machine uses a copy machine, an actual photosensitive drum aging detection operation is periodically performed. To perform automatic correction.

Since the method of using the copier by the user is a general method, it will be omitted, and the following operation will be described assuming that the sensing period (1 hour) for the aging correction of the photosensitive drum is made.

First, the charging charger 1 generates a charging current by generating a corona discharge at a high DC voltage of several KV, and charges the surface of the photosensitive drum 3 according to the voltage applied to the screen grid 2 (see FIG. 4). Competitive phase).

The relationship between the photosensitive drum surface potential and the screen grid surface potential is as follows.

Photosensitive drum surface potential = screen grid surface potential

In this state, the blank lamps 4 (the LEDs are mounted in a row in the shape of rods, and each of the LEDs can be individually turned on and off) can be partially fixed to the third portion (toner). The charge is erased, leaving only the size of the pattern) (the exposure step of FIG. 4).

The developer 5 then attaches toner to the toner pattern portion to produce a toner pattern 12 that is a visible image (development step in FIG. 4).

In this case, three toner patterns 12 are formed at different positions of the photosensitive drum 3 for reliability.

Next, the concentration of the three toner patterns 12 formed by the concentration detection sensor 9 installed at the bottom of the cleaning apparatus 8 is respectively detected (the concentration measurement step in FIG. 4).

When the concentration of the toner pattern 12 formed as described above is detected, the next step is to remove the toner of the toner pattern 12 in which the density measurement is completed, and to make the surface of the photosensitive drum deviate (the cleaning step of FIG. 4).

Thereafter, the antistatic lamp 7 irradiates light on the surface of the photosensitive drum 3 to erase the residual potential (the antistatic step of FIG. 4).

Meanwhile, the three concentration detection values detected by the concentration detection sensor 9 are transmitted to the central processing unit 10 of FIG. 2, and the central processing unit 10 determines whether the three concentration detection values and the drum are old. By comparing the reference value set in advance as a reference to determine the deterioration of the photosensitive drum (3) and thereby determines whether or not the control of the screen grid (2).

That is, as shown in FIG. 5, after forming the three toner patterns 12 formed by the above method (step 1), each of the three toner patterns by using the density detection sensor 9 Detect concentration.

In the next step, the detected three concentration detection values are compared with the reference value to determine whether the reference value exists between the detected three concentration detection values (step 2).

As a result of this check, if the reference value is present between the three concentration detection values, the aging of the photosensitive drum 3 is judged to be normal and normal and the copying is maintained. At this time, there is no voltage change of the screen grid 2.

Next, if the reference value does not exist between the three density detection values, the range of the toner pattern set by the three density detection values is again compared with the reference value (step 3).

As a result of this comparison, when the range of the toner pattern is lower than the reference value, two toner patterns are again formed based on FIG. At this time, the voltage of the screen grid 2 is set to + 100V when the primary toner pattern is formed and + 150V when the secondary toner pattern is formed, respectively, to make two toner patterns (step 4).

Thereafter, the density detection sensor 9 detects the density values of the two newly formed toner patterns, respectively, and checks whether the reference value exists in the detected two concentration detection value ranges (step 5).

At this time, if the reference value is present in the two newly formed concentration detection value ranges, the central processing unit 10 uses the voltages (+ 100V, + 150V) of the screen drawing 2 used to form the two new toner patterns. Is set to a new screen grid voltage to control the screen and voltage converter 11 (step 9). Here, the new screen grid voltage is adopted within the range of the used screen grid voltage (+ 100V, + 200V) for forming the two toner patterns, and most preferably the two screen grid voltages (+ 100V, + 200V) It takes the average.

On the other hand, when the reference value does not exist between the density detection values of the two newly formed toner patterns, the screen and the voltage are again adjusted to + 200V and + 250V, and the new two new toner patterns are adjusted by the method shown in FIG. A toner pattern is formed (step 6).

Then, the concentration detection sensor 9 is used to detect the density of each of the two newly formed toner patterns, and it is determined whether a reference value exists within the two concentration detection value ranges (step 7).

At this time, if the reference value is within the density detection value range of the two toner patterns formed in step 6, the CPU 10 uses the voltage of the screen grid 2 used to form the two new toner patterns. The screen grid voltage converter 11 is controlled by setting (+ 200V, + 250V) to a new screen grid voltage (step 9). The new screen grid voltage is adopted within the range of used screen grid voltages (+ 200V, + 250V) for forming the two toner patterns as described above, and most preferably, the two screen grid voltages (+ 200V, + 250V).

On the contrary, if the reference value does not exist within the two detection value ranges detected when the screen grid voltage is set to + 200V and + 250V, the adjustment of the screen quality alone may not improve the poor copy quality. A bad message is displayed and copying is stopped (step 8).

In addition, if the range of the corner pattern is higher than the reference value as a result of the comparison in step 3, two toner patterns are again made based on FIG. 4 which is the corner pattern forming process. At this time, the voltage of the screen grid 2 is set to -100V when the primary toner pattern is formed and -150V when the secondary toner pattern is formed, respectively, to form two toner patterns (step 10).

Thereafter, the density detection sensor 9 detects the density values of the two newly formed toner patterns, respectively, and checks whether the reference value exists in the detected two concentration detection value ranges (step 11).

At this time, if the reference value is present in the two newly formed concentration detection value ranges, the CPU 10 uses the voltage of the screen grid 2 used to form the two new toner patterns (-100V, -150V). Set to the new screen grid voltage to control the screen grid voltage converter 11 (step 9). The new screen grid voltage is adopted within the range of the used screen grid voltage (-100V, -200V) for forming the two toner patterns, and most preferably the two screen grid voltages (-100V, -150V). It takes the average.

On the other hand, if the reference value does not exist between the density detection values of the two newly formed toner patterns, the screen grid voltage is again adjusted to -200V and -250V to adjust the new two by the same method as in FIG. A toner pattern is formed (step 12).

Then, the density detection sensor 9 is used to detect the concentrations of the two newly formed toner patterns, respectively, and determine whether the reference value exists within the two concentration detection value ranges (step 13).

At this time, if the reference value is within the density detection value range of the two toner patterns formed in step 12, the CPU 10 uses the voltage of the screen grid 2 used to form the two new toner patterns. The screen grid voltage converter 11 is controlled by setting (-200V, -250V) to a new screen grid voltage (step 9). Here, the new screen grid voltage is adopted within the range of the used screen grid voltages (-200V, -250V) for forming the two toner patterns as described above, and most preferably, the two screen grid voltages (-200V, -250V).

On the other hand, if the reference value does not exist within the two density detection values detected when the screen grid voltage is set to -200 V or -250 V, the adjustment of the actual screen grid voltage cannot improve the poor copy quality. A bad message is displayed and copying is stopped (step 8).

In summary, the above-described present invention is briefly summarized by forming an arbitrary toner pattern on the photosensitive drum, detecting the density of the toner pattern and comparing it with a reference value, and if the density detection value is smaller than the reference value, Correcting the screen grid voltage in the direction of increasing the grid voltage to compensate for the degradation of the radiation image quality due to the aging of the photosensitive drum.In contrast, if the density detection value is larger than the reference value, the screen grid voltage is decreased in the direction of lowering the screen grid voltage. By compensating for the degradation of the radiation quality due to the aging of the photosensitive drum.

As described above, in the present invention, an arbitrary toner pattern is formed on a photosensitive drum, the density of the toner pattern is detected and compared with a reference value, and when the density detection value is smaller than the reference value, the screen grid Correcting the screen grid voltage in a direction of increasing the voltage, and automatically correcting the screen grid voltage in a direction of lowering the screen grid voltage when the concentration detection value is greater than the reference value, thereby reducing the photosensitive drum When copy quality is degraded due to aging, it can automatically correct it.

In addition, as described above, the screen grid voltage is automatically corrected when the photosensitive drum is aging, thereby eliminating the inconvenience of requiring the user to directly adjust the screen grid voltage when the radiation image quality is lowered.

Claims (6)

Photosensitive drum detail After forming three toner patterns, the density detection sensor detects the concentration of each of the toner patterns, and compares the three first concentration detection ranges with a preset reference value to correct the photosensitive drum aging. A first step of doing; A second step of determining a magnitude relationship between the reference value and the first concentration detection value range when the reference value exists within the first concentration detection value range as a result of the comparison of the first step; As a result of the determination in the second step, when the first density detection value range is lower than the reference value, a predetermined number of toner patterns are again formed on the photosensitive drum with a new first screen grid voltage, and the predetermined number is detected by the density detection sensor. A third step of comparing the reference value with a second density detection value range obtained by detecting a concentration of a newly formed toner pattern; When the reference value exists within the second concentration detection value range as a result of the comparison in the third step, the screen grid voltage is set within the range of the first screen grid voltage to correct the degradation of radiation image quality due to the aging of the photosensitive drum. The fourth step; If the reference value does not exist within the range of the second density detection value as a result of the comparison in the third step, the second screen grid voltage is set again to form a predetermined toner pattern, and then the predetermined new number is formed by the density detection sensor. A fifth step of comparing the third density detection value range obtained by detecting the density of the toner pattern with the reference value; If the reference value does not exist within the third density detection value range as a result of the comparison in the fifth step, a copy image quality bad message is output and copying is stopped at the same time, and when the reference value is within the third density detection value range, A sixth step of setting the screen grid voltage within the range of the second screen and voltage to correct a deterioration in radiation image quality due to aging of a photosensitive drum; As a result of the determination in the second step, when the first density detection value range is higher than the reference value, a predetermined number of toner patterns are again formed on the photosensitive drum with a new third screen grid voltage, and the predetermined number is detected by the density detection sensor. A seventh step of comparing the fourth density detection value range obtained by detecting the density of the newly formed toner pattern with the reference value; When the reference value is within the fourth concentration detection value range as a result of the comparison in the seventh step, the screen grid voltage is set within the range of the third screen grid voltage to correct the degradation of radiation image quality due to the aging of the photosensitive drum. The eighth step; If the reference value does not exist within the fourth density detection value range as a result of the comparison in the seventh step, the new fourth screen grid voltage is set to form a predetermined toner pattern, and then the predetermined new number is formed by the density detection sensor. A ninth step of comparing the fifth density detection value range obtained by detecting the density of the toner pattern with the reference value; If the reference value does not exist within the fifth density detection value range as a result of the comparison in the ninth step, a copy image quality bad message is output and copying is stopped at the same time, and the reference value exists within the fifth density detection value range. And setting the screen grid voltage within the range of the fourth screen grid voltage to compensate for deterioration of radiation image quality due to aging of the photosensitive drum. A density detecting sensor 9 comprising a light emitting element and a light receiving element for detecting the concentration of the toner pattern 12 temporarily formed on the photosensitive drum 3 to determine whether the photosensitive drum is deteriorated; The density value of the toner pattern detected by the density detection sensor 9 and the photosensitive drum age determination are compared with a preset reference value for changing the screen grid 2 voltage, and the photosensitive drum is judged according to the result. A central processing unit (10) for generating a control signal for changing the voltage of the screen grid (2) when it is determined that the photosensitive drum is old; And a screen grid voltage converter (11) for changing a voltage of the screen grid (2) according to a control signal output from the central processing unit (10). The method of claim 1, wherein the first screen grid voltage for forming a predetermined number of toner patterns is + 100V and + 150V in the third step. The method of claim 1, wherein the second screen grid voltage for forming a predetermined number of toner patterns in the fifth step is + 200V and + 250V. The method of claim 1, wherein the third screen grid voltage for forming the predetermined number of toner patterns in the seventh step is -100V and -150V. The method of claim 1, wherein the fourth screen grid voltage for forming the predetermined number of toner patterns in the ninth step is -200V and -250V.