JPH10333375A - Image recorder - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enable an excellent transfer when the leading end of a recording medium attracted on a transporting belt reaches an image forming section. SOLUTION: This image recorder is provided with a transporting belt 19, an image carrier, a transferring roller 14 forming a transferring section between the image carrier, an attract-electrifying member that is placed in contact with the transporting belt 19 on the upstream side of the transferring section in the traveling direction of the transporting belt 19, a set voltage for attracting electrification is applied thereon and the recording medium 37 fed from a paper feeding mechanism 30 is attracted on the transporting belt 19, and a voltage controlling means capable of controlling the voltage for the attracting electrification and eliminating potential difference between a first point in contact with the transfer roller 14 on the transporting belt 19 and the second point in contact with the attract-electrifying member.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image recording apparatus.

[0002]

2. Description of the Related Art Conventionally, in an image recording apparatus, for example, a color image recording apparatus, image forming sections for yellow, magenta, cyan and black are arranged along a conveyor belt. A toner image of each color is formed in accordance with the data, and the toner image of each color is transferred onto a recording medium which is attracted to the transport belt and sent in a direction perpendicular to the arrangement direction of the recording elements. , A color image is formed.

To this end, the transport belt is stretched between a driving roller and a driven roller, and the recording medium is fed one by one from a paper storage cassette and is disposed to face the driven roller. The sheet is attracted to the conveyor belt by the electrostatic force of the attraction roller.

[0004]

However, in the conventional image recording apparatus, when the front end of the recording medium adsorbed on the conveyance belt by passing through the attraction roller reaches the yellow image forming portion, When a potential difference occurs between a portion of the conveyor belt that contacts the transfer roller and a portion that contacts the driven roller, the transfer voltage and the transfer current fluctuate due to the potential difference. As a result, good transfer cannot be performed in the image forming section.

The present invention solves the problems of the conventional image recording apparatus, and the transfer voltage and the transfer current fluctuate when the front end of the recording medium attracted to the conveyor belt reaches the image forming section. It is an object of the present invention to provide an image recording apparatus capable of performing good transfer in an image forming unit without any problem.

[0006]

For this purpose, in the image recording apparatus of the present invention, a transport belt is provided so as to be able to run freely, and transports a recording medium as it travels, and an image on which a toner image is formed on the surface. A carrier, disposed opposite to the image carrier with the transport belt interposed therebetween, forming a transfer portion between the carrier and the image carrier, and applying a transfer voltage to the toner on the image carrier; A transfer roller for transferring an image to a recording medium, and a transfer roller disposed upstream of the transfer section in the running direction of the transfer belt in contact with the transfer belt, and a set voltage for adsorption and charging is applied to the transfer belt. An attraction / charging member for adsorbing the recording medium sent from the mechanism to the conveyance belt; a first point at which the voltage for the attraction / charging is controlled to contact the transfer roller at the conveyance belt; Between two points And a voltage control means to eliminate the potential difference.

[0007]

Embodiments of the present invention will be described below in detail with reference to the drawings. FIG. 1 is a first schematic diagram of a color image recording apparatus according to an embodiment of the present invention, FIG. 2 is a second schematic diagram of a color image recording apparatus according to an embodiment of the present invention, and FIG. FIG. 4 is a perspective view of the color image forming unit according to the embodiment, and FIG. 4 is a diagram illustrating a state where the color image forming unit according to the present embodiment is located at a retracted position.

As shown in the figure, an image recording device, for example,
In the color image recording apparatus 11, the first to fourth printing mechanisms P <b> 1 to P <b> 4 move from the upstream side (insertion side) to the downstream side (discharge side) in the transport direction of the recording medium 37 along the endless transport belt 19. It is arranged in order. The first to fourth
Have image forming units 12 for yellow, magenta, cyan, and black, respectively. Each of the image forming units 12 of the first to third printing mechanisms P1 to P3 is integrally formed, and
a to form the color image forming unit 25. Further, in order to form a black image, the first
The image forming units 12 of the fourth printing mechanism P4 are formed separately from the image forming units 12 of the third to third printing mechanisms P1 to P3, and are housed in the case 50b.

The first to fourth printing mechanisms P1 to P
Reference numeral 4 includes an electrophotographic LED (light emitting diode) printing mechanism, and has the same structure. Therefore, only the first printing mechanism P1 will be described, and the second to fourth printing mechanisms P2 to P4 will be the first. The description is omitted by giving the same reference numerals as those of the printing mechanism P1. The first printing mechanism P1 includes an image forming unit 12, a print head that performs exposure according to image data, for example, an LED head 13, and a transfer roller that transfers a toner image formed in the image forming unit 12 to a recording medium 37. Consists of fourteen. Note that a laser, a liquid crystal shutter, or the like can be used instead of the LED head 13.

The image forming section 12 includes a photosensitive drum 16 serving as an image carrier which is rotated in the direction of arrow a about a shaft 15, and a charging device for uniformly and uniformly charging the surface of the photosensitive drum 16. It comprises a roller 17 and a developing unit 18. The photosensitive drum 16 and the transfer roller 1
4, a transfer portion is formed. Further, the developing device 18
Is a developing roller 18 formed of a semiconductive rubber material.
a, a developing blade 18b, a sponge roller 18c for supplying an appropriate amount of non-magnetic one-component toner (not shown) to the developing blade 18b, and a toner tank 18d for storing the toner. The toner tank 18d is replaced when the toner runs out.

The toner in the toner tank 18d is sent by a sponge roller 18c to the developing blade 18b by a predetermined amount, and is thinned and adhered to the surface of the developing roller 18a. 16 and is sent to a developing section formed between them. Further, when the toner is thinned, the toner is strongly rubbed (rubbed) by the developing roller 18a and the developing blade 18b to be triboelectrically charged. In this embodiment, the toner is frictionally charged to a negative polarity.

The LED head 13 includes an LED array comprising LED elements (not shown), a drive IC (not shown) for driving the LED array, and a substrate 13 on which a register group (not shown) for holding image data is mounted.
a, a rod lens array 13b for focusing the light of the LED array. And the LED head 13
When image data is input from an interface unit described later, each L of the LED array is associated with the image data.
The ED element emits light, the photosensitive drum 16 is exposed, and an electrostatic latent image is formed on the surface of the photosensitive drum 16. continue,
The toner on the developing roller 18a is made to adhere to the electrostatic latent image by electrostatic force, and the electrostatic latent image becomes a toner image.

The LED head 13 has a spring 13c.
Is pressed against the case 50a. The transport belt 19 is disposed so as to be able to travel between the photosensitive drums 16 of the first to fourth printing mechanisms P1 to P4 and the transfer roller 14, and transports the recording medium 37 as it travels. . By the way, the yellow toner is stored in the toner tank 18d of the developing device 18 in the first printing mechanism P1, and the toner tank 18d of the developing device 18 in the second printing mechanism P2.
Magenta toner, cyan toner in the toner tank 18d of the developing device 18 in the third printing mechanism P3, and black toner in the toner tank 18d of the developing device 18 in the fourth printing mechanism P4. Each is accommodated.

The LED head 13 of the first printing mechanism P1 has yellow image data of the color image data, and the LED head 13 of the second printing mechanism P2 has magenta image data of the color image data. The cyan image data of the color image data is input to the LED head 13 of the third printing mechanism P3, and the black image data of the color image data is input to the LED head 13 of the fourth printing mechanism P4.

As shown in FIG. 3, two camshafts 93A and 93B are rotatably supported below the case 50a of the color image forming unit 25, and are provided at both ends of the camshafts 93A and 93B. The eccentric cam 94 is fixed. On the other hand, a guide groove 93a is formed at the lower four corners of the case 50a so as to fit (engage) with the camshafts 93A and 93B. Further, projecting plate portions 94a are formed at four lower corners of the case 50a so as to be able to abut on the eccentric cam 94.

Therefore, the case 50a is normally pressed downward via the LED head 13 by the urging force of the spring 13c.
The eccentric cam 94 rotates with the rotation of the projection plate 94a.
Is moved up and down, the case 50a is moved in the direction of the arrow h (vertical direction) by the amount of eccentricity of the eccentric cam 94.
As a result, the color image forming unit 25 takes the retracted position shown in FIG. 4 and the operating position shown in FIGS. In the present embodiment, the eccentric cam 94 is used to place the color image forming unit 25 at the retracted position and the operating position, but a rack and pinion (not shown) may be used.

A gear 9 is provided on the camshaft 93A.
5 is fixed, and the gear 95 and the motor gear 96 fixed to the rotation shaft of the cam motor 97 are engaged (engaged).
The camshaft 9 is moved by gears, belts and the like (not shown) provided between the camshafts 93A and 93B.
The rotation of 3A is transmitted to the camshaft 93B. Further, a slit disk 98 is fixed to the camshaft 93A, and a slit 98a is formed in the slit disk 98. The position of the eccentric cam 94 can be known by detecting the slit 98a by the photo sensor 90.

Each L is placed on the upper surface of the case 50a.
A window hole 13d for allowing the ED head 13 to face the photosensitive drum 16 is formed. Further, guide pins 13e and 13f of each LED head 13 are disposed adjacent to the window hole 13d, and each LED head 13 is provided by the guide pins 13e and 13f.
The head 13 is positioned with respect to the color image forming unit 25.

Then, for example, as shown in FIG. 4, the case 50a is moved upward against the urging force of the spring 13c, and the color image forming unit 25 is placed in the retracted position, and the first to third printing is performed. Each photosensitive drum 1 of the mechanisms P1 to P3
6 from the conveyor belt 19, and the fourth printing mechanism P4
By bringing only the photosensitive drum 16 into contact with the conveyor belt 19, a black image can be formed.

The transport belt 19 is formed of a semiconductive plastic film having a high resistance value, and is stretched between a driving roller 20, a driven roller 21, and a stretching roller 22. In this case, the resistance value corresponds to the recording medium 37.
Can be attracted to the conveyor belt 19 by electrostatic force, and when the recording medium 37 is separated from the conveyor belt 19, static electricity remaining on the conveyor belt 19 can be naturally eliminated. It is set to a suitable range.

The drive roller 20 is connected to a motor (not shown), and is rotated in the direction of arrow b by driving the motor. Further, the tension roller 22 is urged in the direction of arrow c by a spring (not shown) to apply tension to the transport belt 19. And the conveyor belt 1
9 includes first to fourth printing mechanisms P1 to P4.
At a time between the respective photosensitive drums 16 and the respective transfer rollers 14. In addition, each of the first to fourth printing mechanisms P1
The transfer belt 19 is brought into contact with the photosensitive drum 16 and the transfer roller 14 in the transfer sections P4 to P4.

A cleaning blade 23 is provided to face the driving roller 20 with the transport belt 19 interposed therebetween.
Pressed to 9. Accordingly, as the transport belt 19 travels, the toner remaining on the surface of the transport belt 19 is scraped off by the cleaning blade 23 and dropped into the waste toner tank 24. In addition,
The cleaning blade 23 is formed of a flexible rubber material, a plastic material, or the like.

On the lower right side of the color image recording apparatus 11 in FIG. 1, a paper feed mechanism 30 is provided. The paper feed mechanism 30 includes a paper storage cassette 30A, a hopping mechanism 30
B, a transport roller 40, and first and second registration rollers 41 and 42 disposed to face the transport roller 40. The paper storage cassette 30A includes a recording medium storage box 31, a push-up plate 32, and a pressing unit 33, and the hopping mechanism 30B includes a discriminating unit 34, a spring 35, and a paper feed roller 36.

In the paper feed mechanism 30, first, the recording medium 37 stored in the recording medium storage box 31 is pressed against the paper feed roller 36 by the pressing means 33 via the push-up plate 32. In this state, when a motor (not shown) is driven to rotate the paper feed roller 36 in the direction of arrow e,
The recording medium 37 sandwiched between the paper feed roller 36 and the discriminating means 34 is guided by guides 38 and 39 and sent between the transport roller 40 and the first registration roller 41.

When the motor (not shown) is driven to rotate the transport roller 40 in the direction of arrow f, the recording medium 37 is transported by the transport roller 40 and the second registration roller 42.
Is transported in the direction of arrow d, guided by guides 81 and 82, and sent between the suction roller 83 and the transport belt 19. The first and second registration rollers 4
The reference numerals 1 and 42 are pressed against the conveying roller 40.

The driven roller 21 contacts the transport belt 19 on the upstream side of the transfer section in the running direction of the transport belt 19, and charges the recording medium 37 sent by the paper feed mechanism 30 together with the suction roller 83, The recording medium 37 is attracted to the conveyor belt 19 by electrostatic force. For this purpose, the suction roller 83 is formed of a semiconductive rubber material having a high resistance value, and is disposed between the suction roller 83 and the driven roller 21 with the transport belt 19 interposed therebetween. Note that the driven roller 21 forms an adsorption charging member. Further, a photo sensor 70 for detecting the front end of the recording medium 37 is provided between the suction roller 83 and the first printing mechanism P1 in the transport direction of the recording medium 37.

Reference numeral 84 denotes a manual feed tray. The operator operates the recording medium 3 along the manual feed tray 84 and the guide 85.
7 can be manually inserted.
Reference numeral 86 denotes a photo sensor for detecting the front end of the recording medium 37 inserted by hand. In this case, the recording medium 37 inserted by hand is conveyed by the conveyance roller 40 and the second registration roller 42, guided by guides 81 and 82, and sent between the suction roller 83 and the conveyance belt 19.

A static eliminator 43 is provided so as to face the upper half 19a of the conveyor belt 19 on the drive roller 20 side. The static eliminator 43 neutralizes the recording medium 37 that has been adsorbed and conveyed by the transport belt 19, releases the attracted state, and facilitates separation of the recording medium 37 from the transport belt 19. Then, to the left of the static eliminator 43 in FIG.
A photo sensor 71 for detecting the rear end of the recording medium 37, a guide 44, and a fixing device 45 are provided. The fixing device 45 includes:
A heat roller 46 for heating the toner on the recording medium 37;
And a pressure roller 47 for pressing the recording medium 37 together with the heat roller 46, and fixes the color toner image formed on the recording medium 37.

Further, a discharge port 48 is disposed on the left side of the fixing device 45 in FIG. 2, and a discharge stacker 49 is disposed outside the discharge port 48. The recording medium 37 on which printing has been completed is discharged to the discharge stacker 49. Is done. Next, a control circuit of the color image recording apparatus 11 having the above configuration will be described. FIG. 5 is a block diagram of a control circuit of the color image recording apparatus according to the embodiment of the present invention.

In the figure, reference numeral 51 denotes a control circuit comprising a microprocessor or the like, and the control circuit 51 controls the entire operation of the color image recording apparatus 11 (FIGS. 1 and 2).
The control circuit 51 includes the first to fourth printing mechanisms P1.
To a P bias power source 5 for applying an SP bias voltage to each sponge roller 18c of each of the developing devices 18 to P4.
2Y, 52M, 52C, and 52B are the developing rollers 18 of the developing units 18 of the first to fourth printing mechanisms P1 to P4.
The DB bias power supplies 53Y, 53M, 53C, 53B for applying a DB bias voltage to
A charging power source 54Y, 54M, 54 for applying a charging voltage to each of the charging rollers 17 of the fourth printing mechanisms P1 to P4.
C and 54B correspond to the first to fourth printing mechanisms P1 to P4, respectively.
The transfer power supplies 55Y, 55M, 55C and 55B for applying a transfer voltage to the respective transfer rollers 14 are connected.
In this embodiment, the transfer power sources 55Y, 55Y
The power supply voltages of the 5M, 55C and 55B are about 500 [V].

The control circuit 51 includes an attraction charging power supply 56 for applying an attraction charging voltage to the driven roller 21.
However, a static elimination power supply 57 for applying a high static elimination voltage to the static eliminator 43 is connected to each. Then, the suction roller 83 is grounded, an electrostatic force is generated by a potential difference formed between the suction roller 83 and the driven roller 21, and the recording medium 37 is suctioned to the transport belt 19 by the electrostatic force. The power supply voltage of the adsorption charging power supply 56 is about 1200 to 1800 [V].

The SP bias power supplies 52Y, 52Y,
2M, 52C, 52B, each DB bias power supply 53Y,
3M, 53C, 53B, each charging power source 54Y, 54M,
54C, 54B, transfer power supplies 55Y, 55M, 55
C, 55B, power supply 56 for adsorption charging and power supply 57 for static elimination
Is turned on / off by an instruction from the control circuit 51.

Further, the control circuit 51 includes first to fourth
The print control circuits 58Y, 58M, 58C and 58B are connected to the print mechanisms P1 to P4, respectively. Then, the print control circuits 58Y, 58M, 58C, 58B
Receives the yellow image signal, the magenta image signal, the cyan image signal, and the black image signal among the color image signals from the memories 59Y, 59M, 59C, and 59B, and transfers them to the LED heads 13 according to an instruction from the control circuit 51. Then, the exposure time of an LED array (not shown) is controlled to form an electrostatic latent image on the surface of each photosensitive drum 16.

To this end, when the interface unit 60 receives a color image signal transmitted from an external device (not shown), for example, a host computer, the interface unit 60 separates the color image signal for each color and outputs yellow image data, magenta image data, It generates cyan image data and black image data, and stores the yellow image data in a memory 59Y.
The magenta image data is stored in the memory 59M, the cyan image data is stored in the memory 59C, and the black image data is stored in the memory 59B.

The fixing device driver 61 controls the fixing device 4.
The heater (not shown) in the heat roller 46 is turned on and off so as to maintain the heat roller 46 at a predetermined temperature. The motor drive circuit 62 includes motors 63 and 64
A, 64B and the cam motor 97 are driven. Then, the paper feed roller 36 is rotated by the motor 63,
The photosensitive drum 16, the charging roller 17, the developing roller 18a, the sponge roller 18c, the transfer roller 14, and the driving roller 2 of the fourth printing mechanism P4 are driven by the motor 64A.
0, the transport roller 40 and the heat roller 46
4B, each photosensitive drum 16, each charging roller 17, and each developing roller 18 of the first to third printing mechanisms P1 to P3.
a, each sponge roller 18c and each transfer roller 14 are respectively rotated. Further, by the cam motor 97,
The color image forming unit 25 can be selectively placed at an operating position and a retracted position.

The first to fourth printing mechanisms P1 to P
4, each photosensitive drum 16, each charging roller 17, each developing roller 18a, each sponge roller 18c, each transfer roller 1
4, the drive roller 20, the transport roller 40, and the heat roller 46 are connected by a gear or a belt (not shown). When the color image forming unit 25 is located at the retracted position, the motor 64A is driven and the motor 64B is stopped. Therefore, the first
The photosensitive drums 16, the charging rollers 17, the developing rollers 18a, the sponge rollers 18c, and the transfer rollers 14 of the third to third printing mechanisms P1 to P3 are stopped. When the motors 64A and 64B are driven, the peripheral speeds of the photosensitive drums 16 and the transport belt 19 are set to be equal to the transport speed of the recording medium 37.

Then, the sensor receiver driver 66
The respective photosensors 70, 71, 86, 90 are operated, and signals of the output waveforms of the respective photosensors 70, 71, 86, 90 are sent to the control circuit 51. Next, the operation of the color image recording device 11 when forming a black image will be described.

First, when the power supply (not shown) of the color image recording apparatus 11 is turned on, the control circuit 51 rotates the cam motor 97 via the motor drive circuit 62, and the slit disk 98 (FIG. 3) by the photo sensor 90. When the slit 98a is detected, the cam motor 97 is stopped.
As a result, the color image forming unit 25 is placed at the retracted position, and each photosensitive drum 16 of the color image forming unit 25 is separated from the transport belt 19.

Thereafter, the control circuit 51 performs predetermined initialization, drives the fixing device driver 61, and warms up the heat roller 46 to a predetermined temperature, and the heat roller 46 is heated to a predetermined temperature. Then, the motor 64A is driven via the motor drive circuit 62, and the drive roller 20 is rotated to move the transport belt 19 in the direction of arrow d. When the transport belt 19 is run slightly longer than one rotation, the motor 64A is stopped and the transport belt 19 is also stopped. As a result, toner, dust, and the like remaining on the surface of the transport belt 19 are scraped off by the cleaning blade 23 and dropped into the waste toner tank 24. During the cleaning operation,
Since the motor 64B is prevented from rotating, the first
The photosensitive drums 16, the charging rollers 17, the developing rollers 18a, and the sponge rollers 18c of the third to third printing mechanisms P1 to P3 do not rotate.

As described above, the color image recording device 11
When the initial setting is completed, the interface unit 60 waits for a black image signal to be transmitted from the external device. When the interface unit 60 receives the black image signal, the control circuit 51 generates black image data based on the black image signal,
One page of black image data to be printed on the recording medium 37 is stored in the memory 59B. In this case, only the black image data is stored in the memory 59B, and the yellow image data, magenta image data, and cyan image data are not stored in the memories 59Y, 59M, and 59C. The control circuit 51 determines whether a black image signal or a color image signal has been sent from the interface unit 60, and when the black image signal has been sent, the color image forming unit 25 is moved to the retracted position, When the image signal is sent, the color image forming unit 25 is placed in the operating position.

Next, the control circuit 51 controls the motor drive circuit 6
When the motor 63 is driven via the drive roller 2 to rotate the paper feed roller 36, the recording medium 37 stored in the storage medium storage box 31 is separated by the discriminating means 34 and the paper feed roller 36, and is fed one by one. You. The fed recording medium 37 is guided by guides 38 and 39, and the front end reaches between the transport roller 40 and the first registration roller 41. Thereafter, by driving the motor 63, It is further transported by a small amount. As a result, the recording medium 37 slightly bends (deflects) when its front end comes into contact with the transport roller 40 and the first registration roller 41, and the skew of the recording medium 37 is corrected by this bending.

Next, the control circuit 51 controls the motor drive circuit 6
The second printing mechanism P4 drives the motor 64A through the second printing mechanism P4.
Photosensitive drum 16, charging roller 17, developing roller 18
a, the sponge roller 18c, the transfer roller 14, the drive roller 20, the transport roller 40, and the heat roller 46 are respectively rotated. At the same time, the control circuit 51
The power supply 56 for suction charging is turned on, and a voltage for suction charging is applied to the driven roller 21.

Accordingly, when the transport roller 40 is rotated, the recording medium 37 is transported by the transport roller 40 and the first and second registration rollers 41 and 42, and is guided by the guides 81 and 82. as a result,
The front end of the recording medium 37 is formed by the suction roller 83 and the transport belt 19.
To reach between. Then, the recording medium 37 is attracted to the transport belt 19 by electrostatic force generated between the driven roller 21 and the attracting roller 83. When the transport roller 40 is further rotated, the recording medium 37 is transported in the direction of arrow d while being attracted to the transport belt 19. Then, the control circuit 51 detects the front end of the recording medium 37 by the photo sensor 70 via the sensor receiver driver 66. When the rear end of the recording medium 37 is separated from the paper feed roller 36, the control circuit 51 stops the motor 63 via the motor drive circuit 62.

Then, the control circuit 51
When 0 detects the front end of the recording medium 37, the charging power supply, the DB bias voltage, and the SP bias voltage are applied to the charging roller 17, the developing roller 18a, and the sponge roller 18c of the fourth printing mechanism P4, respectively. 54
B, DB bias power supply 53B and SP bias power supply 52
Turn B on. Thus, in the fourth printing mechanism P4, the surface of the photosensitive drum 16 is uniformly and uniformly charged by the charging roller 17, and the toner is charged by the developing roller 18a and the sponge roller 18c.

Next, the control circuit 51 includes a memory 59B
To read out one line of black image data from the memory 59B and send the black image data to the print control circuit 58B. The print control circuit 58B converts the black image data sent from the memory 59B according to an instruction from the control circuit 51 into the LE of the fourth printing mechanism P4.
Change to a form that can be transferred to the D head 13 and
Transfer to the D head 13.

Then, the LED head 13 of the fourth printing mechanism P4 turns on the LED array corresponding to the black image data transferred from the printing control circuit 58B, and turns on the -80.
On the surface of the photosensitive drum 16 uniformly and uniformly charged to 0 [V], 1 corresponding to the black image data is provided.
An electrostatic latent image for a line is formed. The surface potential of the image portion of the electrostatic latent image is near 0 [V].

In this manner, the memory 5 is provided for each line.
When the electrostatic latent image is formed on the photosensitive drum 16 in accordance with the black image data read from 9B and the electrostatic latent image is formed in accordance with the length of the black image data in the sub-scanning direction, the exposure is terminated. You. Then, black toner is attached to the surface of the photosensitive drum 16 on which the electrostatic latent image is formed by the electrostatic force of the charged developing roller 18a. Therefore, as the photosensitive drum 16 rotates, the electrostatic latent image is sequentially developed with the black toner to become a black toner image.

When the front end of the recording medium 37 reaches the transfer section of the fourth printing mechanism P4, the control circuit 51 turns on the transfer power supply 55B of the fourth printing mechanism P4. As a result, the transfer roller 14 has + Vty (about 1200 to 1200).
1800 [V]), and the black toner image on the photosensitive drum 16 is transferred to the recording medium 37 line by line. Then, as the photosensitive drum 16 rotates, a black toner image for one page is transferred to the recording medium 37. Thus, the transfer of the black toner image onto the recording medium 37 by the fourth printing mechanism P4 is completed.

When the rear end of the recording medium 37 reaches the transfer portion of the fourth printing mechanism P4, the control circuit 51 determines that the charging power source 54B, the DB bias power source 53B, and the SP power source of the fourth printing mechanism P4 have been used. Bias power supply 52B and transfer power supply 55
Turn B off. Next, the recording medium 37 is
9 to the static eliminator 43. Here, the control circuit 5
In 1, the power supply 57 for static elimination is turned on, and the static eliminator 43 neutralizes the recording medium 37. Thereby, the recording medium 37
Is easily separated from the transport belt 19, is separated from the transport belt 19 on the drive roller 20, is guided by the guide 44, and is sent to the fixing device 45. Then, when the recording medium 37 is separated from the static eliminator 43, the control circuit 51 turns off the static elimination power supply 57.

In the fixing device 45, the black toner image is fixed on the recording medium 37 by the heat roller 46 which has reached a predetermined temperature at which the fixing can be performed, and the pressing roller 47 pressed against the heat roller 46. Thus, a black image is formed. Then, when fixing is completed,
The recording medium 37 is discharged from a discharge port 48 to a discharge stacker 49. In this case, when the photo sensor 71 detects the rear end of the recording medium 37, the control circuit 51
It is known through the sensor receiver driver 66 that 7 has been discharged.

When the ejection of the recording medium 37 is completed, the control circuit 51 stops the motor 64A via the motor drive circuit 62. Also, the manual feed tray 84
Similarly, a black image can be formed on the recording medium 37 inserted from. When the operator sets the recording medium 37 on the manual feed tray 84, the control circuit 5
Reference numeral 1 denotes a case where the recording medium 37 is detected by the photo sensor 86 via the sensor receiver driver 66, and when a black image is formed, the cam motor 97 is driven via the motor drive circuit 62 to move the color image forming unit 25 to the retreat position. Put on. Next, the control circuit 51 includes a motor drive circuit 62
Drives the motor 64A through the photoconductor drum 16, the charging roller 17, and the developing roller 18 of the fourth printing mechanism P4.
a, the sponge roller 18c, the transfer roller 14, the drive roller 20, the transport roller 40, and the heat roller 46 are respectively rotated. At the same time, the control circuit 51
The power supply 56 for suction charging is turned on, and a voltage for suction charging is applied to the driven roller 21.

As a result, the transport roller 40 is rotated, and the recording medium 37 inserted from the manual feed tray 84 is
The sheet is conveyed by the conveyance roller 40 and the second registration roller 42, guided by guides 81 and 82, and reaches a front end between the suction roller 83 and the conveyance belt 19. At this time, the recording medium 37 is attracted to the transport belt 19 by the electrostatic force generated between the driven roller 21 and the attracting roller 83. When the transport roller 40 is further rotated, the recording medium 37 is transported in the direction of arrow d while being attracted to the transport belt 19. Then, the control circuit 51 detects the front end of the recording medium 37 by the photo sensor 70 via the sensor receiver driver 66.
Subsequently, a black image is formed according to the above-described operation.

Next, the operation of the image recording apparatus for forming a color image will be described. Color image recording device 1
When the initial setting of 1 is completed, the interface unit 60 waits for color image data to be transmitted from the external device. Then, when the interface unit 60 receives the color image signal, the control circuit 51 controls the interface unit 60 and the memories 59Y, 59M, 59C, 59B.
The interface unit 60 generates color image data by separating the received color image signal for each color based on the instruction, and stores the yellow image data of the color image data in the memory 59Y. , Magenta image data in the memory 59M, cyan image data in the memory 59C, and black image data in the memory 59B. In this case, the memories 59Y, 59M, 59
C and 59B store yellow image data, magenta image data, cyan image data, and black image data for one page to be printed on the recording medium 37, respectively.

Next, the control circuit 51 controls the motor drive circuit 6
When the motor 63 is driven via the drive roller 2 to rotate the paper feed roller 36, the recording medium 37 stored in the storage medium storage box 31 is separated by the discriminating means 34 and the paper feed roller 36, and is fed one by one. You. Then, the fed recording medium 37 is guided by guides 38 and 39, and the front end reaches between the transport roller 40 and the first registration roller 41. Thereafter, the recording medium 37 is further transported by a small amount.

Subsequently, the control circuit 51 drives the motors 64A and 64B via the motor drive circuit 62, and the photosensitive drums 16, the charging rollers 17, and the photosensitive drums 16 of the first to fourth printing mechanisms P1 to P4. Developing roller 18a, each sponge roller 1
8c, each transfer roller 14, the drive roller 20, the transport roller 40, and the heat roller 46 are rotated. At the same time, the control circuit 51 controls the attraction charging power supply 5.
6 is turned on, and a voltage for suction charging is applied to the driven roller 21.

Therefore, when the transport roller 40 is rotated, the recording medium 37 is transported by the transport roller 40 and the first and second registration rollers 41 and 42 and guided by the guides 81 and 82. As a result, the front end of the recording medium 37 reaches between the suction roller 83 and the transport belt 19. Then, the recording medium 37 is attracted to the transport belt 19 by electrostatic force generated between the driven roller 21 and the attracting roller 83. When the transport roller 40 is further rotated, the recording medium 37 is transported in the direction of arrow d while being attracted to the transport belt 19. Then, the control circuit 51 detects the front end of the recording medium 37 by the photo sensor 70 via the sensor receiver driver 66. When the trailing end of the recording medium 37 is separated from the paper feed roller 36, the control circuit 51 stops the motor 63 via the motor drive circuit 62.

Then, the control circuit 51
0 detects the front end of the recording medium 37, the charging rollers 17 and the developing rollers 1 of the first to fourth printing mechanisms P1 to P4.
In order to apply the charging voltage, the DB bias voltage, and the SP bias voltage to the charging roller 8a and the sponge rollers 18c, respectively, the charging power sources 54Y, 54M, 54C, 54B, the DB bias power sources 53Y, 53M, 53C, 53B, and the SP The bias power supplies 52Y, 52M, 52C and 52B are turned on.

As described above, in each of the first to fourth printing mechanisms P1 to P4, the surface of each photosensitive drum 16 is uniformly and uniformly charged by each charging roller 17, and each developing roller 18a And each sponge roller 18
The toner is charged by c. Next, the control circuit 51 issues an instruction to the memory 59Y, reads one line of yellow image data from the memory 59Y, and sends the yellow image data to the print control circuit 58Y. The print control circuit 58Y converts the yellow image data sent from the memory 59Y according to an instruction from the control circuit 51 into the first image data.
Is changed to a form that can be transferred to the LED head 13 of the printing mechanism P1, and transferred to the LED head 13.

Then, the LED head 13 of the first printing mechanism P1 turns on the LED array corresponding to the yellow image data transferred from the print control circuit 58Y, and turns on the -80.
On the surface of the photosensitive drum 16 uniformly and uniformly charged to 0 [V], 1 corresponding to the yellow image data is provided.
An electrostatic latent image for a line is formed. In this manner, an electrostatic latent image is formed on the photosensitive drum 16 in accordance with the yellow image data read from the memory 59Y line by line, and the electrostatic latent image is formed in accordance with the length of the yellow image data in the sub-scanning direction. Is formed, the exposure ends. And
Yellow toner is attached to the surface of the photosensitive drum 16 on which the electrostatic latent image is formed by the electrostatic force of the charged developing roller 18a. Accordingly, as the photosensitive drum 16 rotates, the electrostatic latent image is sequentially developed with yellow toner to become a yellow toner image.

When the front end of the recording medium 37 reaches the transfer section of the first printing mechanism P1, the control circuit 51 turns on the transfer power supply 55Y of the first printing mechanism P1. As a result, the transfer roller 14 is charged, and the yellow toner image on the photosensitive drum 16 is transferred to the recording medium 37 line by line. Then, as the photosensitive drum 16 rotates, a one-page yellow toner image is transferred to the recording medium 37. Thus, the transfer of the yellow toner image onto the recording medium 37 by the first printing mechanism P1 is completed.

When the rear end of the recording medium 37 reaches the transfer portion of the first printing mechanism P1, the control circuit 51 determines that the charging power source 54Y, the DB bias power source 53Y and the SP power source of the first printing mechanism P1 have been used. The bias power supply 52Y is turned off. Then, the transport belt 19 is continuously run, and the recording medium 37 moves from the first printing mechanism P1 to the second printing mechanism P2. Next, the magenta toner image is formed in the second printing mechanism P2. The image is transferred to the recording medium 37.

That is, the control circuit 51 includes the memory 59M
To read out one line of magenta image data from the memory 59M and send the magenta image data to the print control circuit 58M. The print control circuit 58M converts the magenta image data sent from the memory 59M according to an instruction from the control circuit 51 into the LE of the second print mechanism P2.
Change to a form that can be transferred to the D head 13 and
Transfer to the D head 13.

The LED head 13 of the second printing mechanism P2 turns on the LED array corresponding to the magenta image data transferred from the print control circuit 58M, and uniformly and uniformly charged the photosensitive drum. On the surface of 16,
An electrostatic latent image for one line corresponding to the magenta image data is formed. Thus, according to the magenta image data read from the memory 59M line by line,
When the electrostatic latent image is formed on the photosensitive drum 16 and the electrostatic latent image is formed according to the length of the magenta image data in the sub-scanning direction, the exposure ends. Then, magenta toner is attached to the surface of the photosensitive drum 16 on which the electrostatic latent image is formed by the electrostatic force of the charged developing roller 18a. Therefore, as the photosensitive drum 16 rotates, the electrostatic latent image is sequentially developed with magenta toner to form a magenta toner image.

When the front end of the recording medium 37 reaches the transfer section of the second printing mechanism P2, the control circuit 51 turns on the transfer power supply 55M of the second printing mechanism P2. As a result, the transfer roller 14 is charged, and the magenta toner image on the photosensitive drum 16 is transferred to the recording medium 37 line by line. Then, with the rotation of the photosensitive drum 16, the magenta toner image for one page is superimposed and transferred on the yellow toner image on the recording medium 37. Thus, the transfer of the magenta toner image onto the recording medium 37 by the second printing mechanism P2 is completed.

Next, the recording medium 37 further moves from the second printing mechanism P2 to the third printing mechanism P3, and the cyan toner image is transferred to the recording medium 37 in the third printing mechanism P3. Then, when the cyan toner image is transferred to the recording medium 37, the recording medium 37 moves from the third printing mechanism P3 to the fourth printing mechanism P4, and the black toner image is formed in the fourth printing mechanism P4. The image is transferred to the recording medium 37. In general, when forming a color image, black is used for inking by under color removal (UCR) or the like. Therefore, even when a color image is formed, the photosensitive drum 16 of the fourth printing mechanism P4 is brought into contact with the transport belt 19.

As described above, the toner image of each color is recorded on the recording medium 3.
7 and are sequentially transferred to form a color toner image. Subsequently, the recording medium 37 is sent to the static eliminator 43 by the transport belt 19. Here, the control circuit 51 turns on the charge elimination power supply 57 and turns on the recording medium 37 by the charge eliminator 43.
To remove electricity. Thereby, the recording medium 37 is easily separated from the transport belt 19, is separated from the transport belt 19 on the drive roller 20, is guided by the guide 44, and is sent to the fixing device 45. When the recording medium 37 is separated from the static eliminator 43, the control circuit 51 outputs a static elimination power supply 57.
Turn off.

In the fixing device 45, a color toner image is fixed on the recording medium 37 by a heat roller 46 which has reached a predetermined temperature at which fixing is possible, and a pressure roller 47 pressed against the heat roller 46. Thus, a color image is formed. When the fixing is completed, the recording medium 37 is discharged from the discharge port 48 to the discharge stacker 49. In this case, the control circuit 51 includes a photo sensor 71
Detects the trailing end of the recording medium 37, it knows through the sensor receiver driver 66 that the recording medium 37 has been ejected.

When the ejection of the recording medium 37 is completed, the control circuit 51 stops the motors 64A and 64B via the motor drive circuit 62. When the transfer of the toner image for one page is completed in the first printing mechanism P1, the transfer power supply 55Y is turned off. Similarly, for the second to fourth printing mechanisms P2 to P4, when the transfer of the toner image for one page is completed, the transfer power supply 5 is sequentially turned on.
5M, 55C, 55B are turned off.

As described above, a color image can be formed on the recording medium 37 fed by the paper feeding mechanism 30.
Further, a color image can be similarly formed on the recording medium 37 inserted from the manual feed tray 84. In this case, when the operator sets the recording medium 37 on the manual feed tray 84, the control circuit 51 detects the recording medium 37 by the photo sensor 86 via the sensor receiver driver 66, and then detects the recording medium 37 via the motor drive circuit 62. Motor 64A,
64B, and drives each photosensitive drum 16, each charging roller 17, each developing roller 18a, each sponge roller 18c, each transfer roller 14, of each of the first to fourth printing mechanisms P1 to P4,
Then, the drive roller 20, the transport roller 40, and the heat roller 46 are rotated. At the same time, the control circuit 51 turns on the suction charging power supply 56 to turn on the driven roller 2.
1 is applied with a voltage for adsorption charging.

As a result, the transport roller 40 is rotated, and the recording medium 37 inserted from the manual feed tray 84 is
The sheet is conveyed by the conveyance roller 40 and the second registration roller 42, guided by guides 81 and 82, and reaches a front end between the suction roller 83 and the conveyance belt 19. At this time, the recording medium 37 is attracted to the transport belt 19 by the electrostatic force generated between the driven roller 21 and the attracting roller 83. When the transport roller 40 is further rotated, the recording medium 37 is transported in the direction of arrow d while being attracted to the transport belt 19. Then, the control circuit 51 detects the front end of the recording medium 37 by the photo sensor 70 via the sensor receiver driver 66.
Subsequently, a color image is formed according to the above-described operation.

Next, the operation of the adsorption charging power supply 56 will be described. FIG. 6 is a diagram illustrating an equivalent circuit of a transfer unit, a driven roller, and a suction roller of the first printing mechanism P1 according to the embodiment of the present invention. FIG. It is a flowchart. In this case, FIG. 6 shows a state in which the recording medium 37 (FIG. 1) is conveyed while being attracted to the conveyor belt 19, and the front end of the recording medium 37 has passed through the attraction roller 83 and reached the transfer section.

Also, Z_OPC, Z_FIX, Z_P, Z_TRIs
Each of the photosensitive drum 16, the suction roller 83, and the recording medium 3
7 and the impedance of the transfer roller 14. Soshi
And Z _BVAnd Z_BSIs the volume direction of the conveyor belt 19
And surface impedance, R ₁, R_TwoIs the charge for adsorption
A resistor for controlling the source 56. A is the conveyor belt 1
9, the first point in contact with the transfer roller 14, B
The second contact of the feed belt 19 with the driven roller 21
Point, V_A, V_BAre the potentials at the first and second points A and B, respectively.
You.

When only one recording medium 37 accommodated in the recording medium accommodation box 31 is fed out and sent to the attraction roller 83, the control circuit 51 turns on the attraction power source 56 to turn on the driven roller 21. Apply a voltage for adsorption charging,
The recording medium 37 is made to adhere to the transport belt 19. At this time, the voltage applied to the driven roller 21 is
Is set as appropriate depending on the type of.

Subsequently, when the front end of the recording medium 37 reaches the transfer section of the first printing mechanism P1, the control circuit 51 turns on the transfer power supply 55Y to apply a transfer voltage to the transfer roller 14, and The toner image formed on the drum 16 is transferred to the recording medium 37. At this time, the transfer voltage applied to the transfer roller 14 is appropriately set according to the type of the recording medium 37.

By the way, when the front end of the recording medium 37 reaches the transfer portion of the first printing mechanism P1 and the transfer power supply 55Y is turned on, there is a potential difference between the first and second points A and B. Then, a current flows between the first and second points A and B. As a result, the transfer current I _TR varies, the transcriptional current I _TR is out of good range transfer, it is impossible to perform good transfer.

Then, when the front end of the recording medium 37 reaches the transfer section of the first printing mechanism P1 and the transfer power supply 55Y is turned on, the voltage control means (not shown) of the control circuit 51 causes each resistor R _1, the voltage between the R ₂ of the terminal V _R1, V _R2
Are detected by the buffers 101 and 102, respectively, and the potential difference between the first and second points A and B is detected based on the outputs of the buffers 101 and 102.

Here, each potential V at the first and second points A and B is
_A, V _B is the case where V _A> V _B, by increasing the current I _FIX, also if a V _A <V _B, and controls the attraction charging power supply 56, a current I
_FIX reduces to V _A = V _B to. Therefore, the potential difference between the first and second points A and B disappears, so that when the front end of the recording medium 37 adsorbed on the transport belt 19 reaches the transfer section of the first printing mechanism P1, the transfer voltage and The transfer current I _TR does not change, and good transfer can be performed in the transfer portion.

Next, the flowchart will be described. Step S1: Wait until the recording medium 37 reaches the suction roller 83. Step S2: The power supply 56 for adsorption charging is turned on. Step S3: Wait until the recording medium 37 reaches the transfer section of the first printing mechanism P1. Step S4: The transfer power supply 55Y is turned on. Step S5 and the potential V _A and the potential V _B is whether to determine equality. To step S9 if there is a potential V _A and the potential V _B equal, not equal, the process proceeds to step S6. Step S6 potential V _A to determine whether a potential higher than V _B. To step S7 if the potential V _A is greater than the potential V _B, if the potential V _A is equal to or less than the potential V _B goes to step S8. Step S7: Increase the current I _FIX and return to step S5. Step S8: Decrease the current I _FIX and return to step S5. Step S9: It is determined whether the recording medium 37 has passed the transfer section of the first printing mechanism P1. If the recording medium 37 has passed through the transfer section of the first printing mechanism P1, the process ends, and if not, the process returns to step S5.

The present invention is not limited to the above-described embodiment, but can be variously modified based on the gist of the present invention, and they are not excluded from the scope of the present invention.

[0080]

As described above in detail, according to the present invention, the image recording apparatus is provided so as to be able to run freely,
A conveyance belt that conveys the recording medium as it travels, an image carrier on which a toner image is formed on the surface, and an image carrier that is disposed to face the image carrier with the conveyance belt interposed therebetween. A transfer roller that transfers a toner image on the image carrier to a recording medium by applying a transfer voltage to the recording medium; and a transfer belt upstream of the transfer unit in a running direction of the transfer belt. Is disposed in contact with, a set voltage for adsorption charging is applied, and an adsorption charging member that adsorbs the recording medium sent from the sheet feeding mechanism to the transport belt, and controls the voltage for adsorption charging, A voltage control unit that eliminates a potential difference between a first point of the transport belt that contacts the transfer roller and a second point that contacts the adsorption charging member.

In this case, the recording medium sent from the paper feeding mechanism is attracted to the transport belt by the attracting and charging member, and is transported to the transfer section as the transport belt travels. And the voltage for adsorption charging is controlled by the voltage control means,
The potential difference between the first point in contact with the transfer roller and the second point in contact with the adsorption charging member on the transport belt is eliminated.

Therefore, the transfer voltage and the transfer current do not change, and good transfer can be performed in the transfer section.

[Brief description of the drawings]

FIG. 1 is a first schematic diagram of a color image recording apparatus according to an embodiment of the present invention.

FIG. 2 is a second schematic diagram of the color image recording apparatus according to the embodiment of the present invention.

FIG. 3 is a perspective view of a color image forming unit according to the embodiment of the present invention.

FIG. 4 is a diagram illustrating a state where the color image forming unit according to the exemplary embodiment is placed at a retracted position.

FIG. 5 is a block diagram of a control circuit of the color image recording apparatus according to the embodiment of the present invention.

FIG. 6 shows a first printing mechanism P according to the embodiment of the present invention.
FIG. 3 is a diagram illustrating an equivalent circuit of a transfer unit, a driven roller, and a suction roller of FIG.

FIG. 7 is a flowchart showing an operation of a power supply for adsorption charging according to the embodiment of the present invention.

[Explanation of symbols]

11 color image recording apparatus 14 transfer roller 16 photosensitive drum 19 the conveyor belt 21 driven roller 30 the paper feed mechanism 37 recording medium 51 control circuit 56 attraction charging power supply A first point B the second point V _A, V _B potential

 ──────────────────────────────────────────────────の Continuing from the front page (72) Inventor Hiroyuki Inoue 4-11-12 Shibaura, Minato-ku, Tokyo Inside Oki Data Corporation

Claims (2)

[Claims] 1. A transport belt, which is disposed so as to be able to run freely and transports a recording medium as it travels, (b) an image carrier on which a toner image is formed on the surface, and (c) the transport belt And a transfer portion formed between the image bearing member and the image bearing member, and a transfer voltage is applied to transfer the toner image on the image bearing member to a recording medium. A transfer roller, (d) disposed in contact with the transport belt on the upstream side of the transfer section in the traveling direction of the transport belt, applied with a set voltage for adsorption charging, and sent from the paper feed mechanism. (E) a first point at which the voltage for the attraction charging is controlled to contact the transfer roller, and a second point at which the recording medium contacts the attraction charging member. Voltage control means for eliminating the potential difference between An image recording apparatus comprising: 2. The voltage control unit according to claim 1, wherein when the front end of the recording medium reaches the transfer unit, the voltage control unit controls a voltage for attraction charging to eliminate a potential difference between the first and second points.
The image recording apparatus according to claim 1.