JP2020170043A - Image formation device - Google Patents

Abstract

To provide an image formation device that does not easily damage a photoreceptor drum and a belt device.SOLUTION: An image formation device 1 includes: a plurality of photoreceptor drums 51 including an input coupling 71; a belt device 40 disposed to face the photoreceptor drums; an output coupling 72 for transmitting drive force to the input coupling; a drive unit 8 including a motor 81 for outputting the drive force, a drive train 83 for transmitting the drive force to the output coupling, and a switching unit 82 for switching the drive force so that the rotation direction of the output coupling is forward or reverse; a torque limiter 839 capable of stopping the transmission of the drive force when the output coupling provided in the drive train is reversely rotated; and a CPU 91. The CPU performs a first mode in which the switching unit is controlled so that the output coupling rotates in a reverse rotation direction when the belt device is stopped and a second mode in which the switching unit is controlled so that the belt drive is driven and the output coupling rotates in a forward rotation direction.SELECTED DRAWING: Figure 4

Description

The present invention relates to an electrophotographic image forming apparatus.

Conventionally, in an electrophotographic image forming apparatus, a configuration is known in which a driving force from a driving source is transmitted to a photoconductor drum by using a coupling. When the image forming apparatus having such a configuration has a plurality of photoconductor drums, the timing at which the couplings of the respective photoconductor drums are connected is deviated, so that the photoconductor drums whose rotation has not yet started If the drive of the transport belt that comes into contact with the photoconductor drum is started at a certain time, a peripheral speed difference may occur between the non-rotated photoconductor drum and the transport belt, and the photoconductor drum may be damaged.

Therefore, as disclosed in Patent Document 1, by starting the driving of the transport belt after starting the driving of the plurality of photoconductor drums and before connecting the couplings of all the photoconductor drums, the photosensitivity is exhibited. The time during which the peripheral speed difference occurs between the body drum and the transport belt is shortened so that the photoconductor drum and the transport belt are not damaged as much as possible.

JP-A-2010-79160

According to the above technique, since the transport belt is started to be driven before all the couplings of the photoconductor drum are connected, it is possible to prevent damage to some extent. However, since the transfer belt is started in the state where the photoconductor drum to which the coupling is not connected is present, the photoconductor drum and the transfer belt are not a little damaged.

Therefore, the present invention provides an image forming apparatus in which damage to a belt apparatus such as a photoconductor drum and a transport belt is less likely to occur than in the prior art.

An image forming apparatus that solves the above problems has the following features.
That is, the image forming apparatus (1) is an electrophotographic image forming apparatus (1), and is detachable from the apparatus main body (2) and the apparatus main body (2), and a driving force is input. A first photoconductor drum (51-1) having a first input coupling (71) and a second input coupling (71) that is detachable from the device body (2) and to which a driving force is input. A second photoconductor drum (51-2), a belt device (40) arranged to face the first photoconductor drum (51-1) and the second photoconductor drum (51-2), and the device. A first output coupling (72) provided in the main body (2) and transmitting a driving force to the first input coupling (71), and a second input coupling (71) provided in the apparatus main body (72). The second output coupling (72) that transmits the driving force to, the driving source (81) that outputs the driving force, and the driving force output from the driving source (81) are transferred to the first output coupling (72). ) And the drive train (83) transmitted to the second output coupling (72), and the driving force output from the drive source (81) are transferred to the first output coupling (72) and the second output cup. A drive unit (8) having a switching unit (82) for switching the rotation direction of the ring (72) to a forward rotation direction or a reverse rotation direction for forming an image, and a drive unit (83) provided in the drive row (83). When the first output coupling (72) and the second output coupling (72) are rotating in the reverse rotation direction, the first output coupling (72) and the second output coupling (72) become A torque limiter (839) that stops transmission of the driving force to the first output coupling (72) and the second output coupling (72) when a torque equal to or higher than a predetermined value is applied, and the driving unit (8). And a control unit (91) for controlling the drive of the belt device (40), the control unit (91) has the first output coupling (72) with the belt device (40) stopped. The first mode for controlling the switching unit (82) so that the second output coupling (72) rotates in the reverse rotation direction, the belt device (40), and the first output coupling are driven. (72) and the second mode for controlling the switching unit (82) so that the second output coupling (72) rotates in the forward rotation direction are executed.

According to the present invention, when the first mode is executed, the output coupling and the input coupling can be engaged while suppressing the occurrence of damage to the photoconductor drum and the belt device. Further, when the second mode is executed, it is possible to perform image formation.

It is a central sectional view which shows the image forming apparatus. It is a schematic side view which shows the opening and the front cover of the apparatus main body. It is a figure which shows the coupling which transmits the driving force to a photoconductor drum. It is a side view which shows the 1st Embodiment of the drive part of an output coupling. It is a block diagram which shows the electric structure for drive control of a photoconductor drum. It is a flowchart which shows the drive control of a photoconductor drum. It is a side view which shows the drive part which concerns on 1st Embodiment, and is configured so that the rotation speed of a motor at the time of execution of 1st mode is faster than at the time of execution of 2nd mode. It is a figure which shows the lock mechanism. It is a side view which shows the 2nd Embodiment of the drive part of an output coupling. It is a side view which shows the drive part which concerns on 2nd Embodiment, and is configured so that the rotation speed of a motor at the time of execution of 1st mode is faster than at the time of execution of 2nd mode. It is a side view which shows the 3rd Embodiment of the drive part of an output coupling. It is a side view which shows the drive part which concerns on 2nd Embodiment, and is configured so that the rotation speed of a motor at the time of execution of 1st mode is faster than at the time of execution of 2nd mode. (A) is a schematic side view showing the device main body according to the second embodiment, and (b) is a schematic side view showing the device main body according to the third embodiment.

Next, a mode for carrying out the present invention will be described with reference to the accompanying drawings.

[Overall configuration of image forming device]
The image forming apparatus 1 shown in FIG. 1 is an embodiment of the image forming apparatus according to the present invention, and is a color laser printer that forms an image of a plurality of colors on paper S by an electrophotographic method.
In the following description, the front-back, left-right, and up-down directions are determined with reference to the state in which the image forming apparatus 1 is usably installed as shown in FIG.

The image forming apparatus 1 includes an apparatus main body 2, a paper feeding unit 3 having a paper feeding tray 10 and a paper conveying unit 30, and an image forming unit 5 that forms an image on the paper S conveyed by the paper feeding unit 3. I have.

The apparatus main body 2 is formed in a substantially rectangular parallelepiped shape, and houses a paper feeding unit 3 and an image forming unit 5. An opening 2A is formed on the front surface 21 of the apparatus main body 2. The device main body 2 has a front cover 22 capable of opening and closing the opening 2A. The front surface 21 is an example of an opening surface on which an opening is formed. The front cover 22 is an example of a cover whose opening can be opened and closed.

A paper output tray 23a that inclines downward from the front side to the rear side is formed on the upper surface 23 of the apparatus main body 2.

The paper feeding unit 3 is arranged at the lower part of the apparatus main body 2, and conveys the paper S supported by the paper feeding tray 10 to the image forming unit 5 by the paper conveying unit 30. The paper feed tray 10 is configured to be slidable in the front-rear direction, and is configured to be movable between a storage position housed in the apparatus main body 2 and a separation position pulled forward from the storage position.

The paper transport unit 30 includes a paper feed roller 32, a separation roller 33, a separation pad 33a, a transport roller pair 34, and a resist roller pair 35. A transport path P for the paper S from the paper feed tray 10 to the paper output tray 23a via the image forming unit 5 is configured in the apparatus main body 2.

The paper S supported by the paper feed tray 10 is separated one by one by the paper feed roller 32, the separation roller 33, and the separation pad 33a, and is sent out to the transport path P. The paper feed roller 32 is a roller that conveys the paper S from the paper feed tray 10 toward the image forming unit 5. The separation roller 33 and the separation pad 33a form a separation means for separating the paper S supported by the paper feed tray 10 one by one.

The paper S sent out to the transport path P is transported toward the image forming unit 5 by the transport roller pair 34 and the resist roller pair 35. The resist roller pair 35 regulates the movement of the tip of the paper S to be transported and temporarily stops the paper S, and then transports the paper S toward the image forming unit 5 at a predetermined timing.

The image forming unit 5 is arranged above the paper feeding unit 3, and includes four drum units 50 arranged side by side in the front-rear direction. Each drum unit 50 is provided corresponding to each color of black, yellow, magenta, and cyan. The drum unit 50 includes a photoconductor drum 51 and a developing roller 52.

Hereinafter, regarding the four photoconductor drums 51 provided in the image forming unit 5, the photoconductor drums 51 arranged on the most upstream side in the paper transport direction are the first photoconductor drum 51-1 and the first photoconductor drum 51. The photoconductor drum 51 arranged on the downstream side in the paper transport direction from -1 is arranged on the second photoconductor drum 51-2 and the photosensitizer drum 51 arranged on the downstream side in the paper transport direction with respect to the second photoconductor drum 51-2. The body drum 51 is required to be the third photoconductor drum 51-3, and the photoconductor drum 51 arranged on the downstream side in the paper transport direction from the third photoconductor drum 51-3 is required to be the fourth photoconductor drum 51-4. Describe as appropriate according to.

The image forming unit 5 includes an exposure unit 53 that exposes the surface of the photoconductor drum 51, and a fixing device 60 that is arranged on the downstream side of the photoconductor drum 51 in the transport direction of the paper S. The photoconductor drum 51 is configured to be removable from the device main body 2 via an opening 2A formed in the front surface 21 of the device main body 2.

A transfer belt 41 is arranged to face each other below the transport path P of the photoconductor drum 51. The transfer belt 41 is hung between the drive roller 42 and the driven roller 43 arranged in front of the drive roller 42. The belt device 40 is composed of a transfer belt 41, a drive roller 42, and a driven roller 43. A transfer roller 44 is arranged at a position facing each photoconductor drum 51 with the transfer belt 41 sandwiched between them.

In the image forming unit 5, the photoconductor drum 51 uniformly charged by the charger is selectively exposed by the exposure unit 53, respectively. By this exposure, electric charges are selectively removed from the surface of the photoconductor drum 51, and an electrostatic latent image is formed on the surface of the photoconductor drum 51.

A development bias is applied to the developing roller 52, and when the electrostatic latent image formed on the photoconductor drum 51 faces the developing roller 52, the potential difference between the electrostatic latent image and the developing roller 52 causes the developing roller. Toner is supplied from 52 to the electrostatic latent image. As a result, a toner image is formed on the surface of the photoconductor drum 51.

When the paper S conveyed toward the image forming unit 5 reaches the transfer belt 41, it is conveyed by the transfer belt 41 and sequentially passes between the transfer belt 41 and each photoconductor drum 51. Then, the toner image on the surface of the photoconductor drum 51 is transferred to the paper S by the transfer bias applied to the transfer roller 44 when facing the paper S.

The transfer belt 41 in the present embodiment is configured as a transport belt that conveys the paper S on which the toner image is transferred, but the toner image is transferred to the belt itself, and the toner image transferred to the belt is further transferred to the paper. It can also be configured as an intermediate transfer belt that is transferred to S.

The paper S on which the toner image is transferred is conveyed to the fixing device 60. The fixing device 60 includes a heating roller 61 and a pressure roller 62 that presses against the heating roller 61, and the paper S conveyed to the fixing device 60 passes between the heating roller 61 and the pressure roller 62. The toner image is heat-fixed.

The paper S on which the toner image is thermally fixed is conveyed from the fixing device 60 to the downstream side in the conveying direction, and is further arranged on the downstream side of the intermediate paper ejection roller pair 63 and the intermediate paper ejection roller pair 63 in the conveying direction. It is conveyed by pair 64 and is discharged to the output tray 23a on the upper surface 23.

As shown in FIG. 2, the front cover 22 provided on the front surface 21 of the apparatus main body 2 is configured to be rotatable around a rotation shaft portion 22a at the lower end portion, and is a detector projecting rearward at the upper end portion. It has 22b. The device main body 2 has an open / close sensor 94 that detects the open / close of the front cover 22. The open / close sensor 94 is arranged at the front end and the upper end of the apparatus main body 2. The open / close sensor 94 is an example of a sensor that detects the open / close of the cover.

The open / close sensor 94 detects the detector 22b when the front cover 22 is closed and closes the opening 2A, and detects that the front cover 22 is closed by detecting the detector 22b. Further, the open / close sensor 94 does not detect the detector 22b when the front cover 22 is open and the opening 2A is open, and detects that the front cover 22 is open by not detecting the detector 22b. ..

[Photoreceptor drum drive mechanism]
The photoconductor drum 51 is driven via the coupling 7 by a driving force output from the motor 81 (see FIG. 5). As shown in FIG. 3, the photoconductor drum 51 is driven by a driving force from the motor 81 to rotate about the rotation axis C. The coupling 7 is arranged at one side end of the photoconductor drum 51 in the left-right direction. In the left-right direction, a drum gear 54 that can rotate integrally with the photoconductor drum 51 is provided between the photoconductor drum 51 and the coupling 7.

The couplings 7 are an input coupling 71 that is integrally rotatably provided on the photoconductor drum 51 and to which a driving force is input, and an output coupling 72 that is provided on the apparatus main body 2 and transmits the driving force to the input coupling 71. And have.

The input coupling 71 provided on the first photoconductor drum 51-1 is an example of the first input coupling, and the output coupling that transmits the driving force to the input coupling 71 provided on the first photoconductor drum 51-1. 72 is an example of the first output coupling. The input coupling 71 provided on the second photoconductor drum 51-2 is an example of the second input coupling, and the output coupling that transmits the driving force to the input coupling 71 provided on the second photoconductor drum 51-2. 72 is an example of the second output coupling.

The input coupling 71 and the output coupling 72 are arranged so as to face each other in the left-right direction, and the output coupling 72 is arranged on the left and right outside of the input coupling 71. On the surface of the output coupling 72 facing the input coupling 71, a protrusion 72a protruding toward the input coupling 71 side is formed, and the output coupling 72 is configured to be movable in the left-right direction. .. A concave groove 71a into which the protrusion 72a can be fitted is formed on the surface of the input coupling 71 facing the output coupling 72.

The output coupling 72 is configured to be rotatable about the rotation axis C, and when the protrusion 72a is not fitted with the concave groove 71a, the output coupling 72 and the input coupling 71 rotate relatively. It is possible. Further, when the protrusion 72a is fitted with the concave groove 71a, the output coupling 72 and the input coupling 71 can rotate integrally.

The output coupling 72 is displaceable in the left-right direction and is urged toward the input coupling 71 by a spring 73, and the protrusion 72a fits into the concave groove 71a as shown in FIG. 3A. When the output coupling 72 in the non-exposed state rotates relative to the input coupling 71 and the positions of the protrusion 72a and the concave groove 71a in the circumferential direction match, as shown in FIG. 3B. The protrusion 72a is configured to fit into the concave groove 71a by the urging force of the spring 73.

The concave groove 71a is formed at one place in the circumferential direction of the input coupling 71, the protrusion 72a is formed at one place in the circumferential direction of the output coupling 72, and the protrusion 72a always fits into the same concave groove 71a. It is configured to do.

That is, the coupling 7 is configured as a one-phase coupling, and the output coupling 72 corresponding to one photoconductor drum 51 (for example, the first photoconductor drum 51-1) and the input coupling 71 mesh with each other. The phase can always be matched with the phase in which the output coupling 72 and the input coupling 71 corresponding to another photoconductor drum 51 (for example, the second photoconductor drum 51-2) mesh with each other. As a result, it is easy to correct the dimensional error of the photoconductor drum 51, and it is possible to reduce the color shift of each color at the time of image formation.

The output coupling 72 is configured to be rotatable in a forward rotation direction, which is a rotation direction when image formation is performed by the image forming unit 5, and a reverse rotation direction, which is a rotation direction opposite to the forward rotation direction. .. A gear portion 72b is formed on the outer peripheral portion of the output coupling 72.

As shown in FIG. 4, the image forming apparatus 1 has a driving unit 8 for driving the output coupling 72. The drive unit 8 includes a motor 81, a switching unit 82, and a drive train 83. The motor 81 is an example of a drive source that outputs a driving force.

The switching unit 82 is a switching mechanism that switches the driving force output from the motor 81 so that the rotation direction of the output coupling 72 is the forward rotation direction or the reverse rotation direction for forming an image, and is driven by the motor 81. It has a first drive gear 821 to which a force is input and a solenoid 822.

The drive train 83 is a transmission mechanism that transmits the driving force output from the motor 81 to the output coupling 72. The drive train 83 includes a first transmission gear 831, a second transmission gear 832 coaxially arranged with the first transmission gear 831 and rotatable integrally, and a third transmission gear 833 that meshes with the second transmission gear 832. It has a fourth transmission gear 834 that meshes with the third transmission gear 833. The first transmission gear 831 is meshable with the first drive gear 821, and the fourth transmission gear 834 is meshed with the gear portion 72b of the output coupling 72.

Further, the drive row 83 includes a fifth transmission gear 835 that meshes with the fourth transmission gear 834, a sixth transmission gear 836 that meshes with the fifth transmission gear 835, and a seventh transmission gear 837 that meshes with the sixth transmission gear 836. It has an eighth transmission gear 838 that meshes with the seventh transmission gear 837. The fifth transmission gear 835 can mesh with the first drive gear 821. The seventh transmission gear 837 is connected to the drive roller 42 of the belt device 40, and the eighth transmission gear 838 is connected to the developing roller 52.

The first transmission gear 831, the second transmission gear 832, the third transmission gear 833, and the fourth transmission gear 834 form the first drive row 83a. As shown in FIG. 4B, in the first drive row 83a, the driving force from the motor 81 is input when the first driving gear 821 is engaged with the first transmission gear 831, and the input driving force is input. It is a drive train transmitted to the output coupling 72. When the driving force from the motor 81 rotating in the forward rotation direction is transmitted to the output coupling 72 by the first drive row 83a, the output coupling 72 rotates in the reverse rotation direction.

The second transmission gear 832 is formed to have a larger diameter than the first transmission gear 831, and the first transmission gear 831 and the second transmission gear 832 form a two-stage gear. As a result, the driving force input to the first transmission gear 831 is accelerated and output from the second transmission gear 832. The third transmission gear 833 has a torque limiter 839, and when a torque of a predetermined value or more is applied to the output coupling 72 when the output coupling 72 is rotating in the reverse rotation direction, the third transmission gear 833 The transmission of the driving force to the output coupling 72 is stopped by the torque limiter 839. The torque limiter 839 is provided in the first drive row 83a.

When the output coupling 72 is rotating in the reverse rotation direction, when the output coupling 72 and the input coupling 71 are fitted and can rotate integrally, the photoconductor drum 51 is attached to the output coupling 72. Although the torque it has is applied, in the present embodiment, when the torque possessed by the photoconductor drum 51 is applied to the output coupling 72, the torque limiter 839 stops transmitting the driving force to the output coupling 72. It is set to do.

The fifth transmission gear 835 and the fourth transmission gear 834 constitute the second drive row 83b. As shown in FIG. 4A, in the second drive row 83b, the driving force from the motor 81 is input when the fifth transmission gear 835 is engaged with the first driving gear 821, and the input driving force is input. It is a drive train transmitted to the output coupling 72. When the driving force from the motor 81 rotating in the forward rotation direction is transmitted to the output coupling 72 by the second drive row 83b, the output coupling 72 rotates in the forward rotation direction.

The sixth transmission gear 836, the seventh transmission gear 837, and the eighth transmission gear 838 constitute the third drive row 83c. As shown in FIG. 4A, the sixth transmission gear 836 is the sixth when the fifth transmission gear 835 meshes with the first drive gear 821 and the fifth transmission gear 835 is driven by the first drive gear 821. 7 It is configured to move to a position where it meshes with the transmission gear 837.

When the sixth transmission gear 836 is moved to a position where it meshes with the seventh transmission gear 837, the driving force from the fifth transmission gear 835 driven by the first drive gear 821 is applied to the seventh transmission gear 837 and the eighth transmission gear. It is transmitted to 838, and the drive roller 42 and the developing roller 52 of the belt device 40 are driven.

As shown in FIG. 4B, in the sixth transmission gear 836, the fifth transmission gear 835 does not mesh with the first drive gear 821, and the fifth transmission gear 835 is driven by the fourth transmission gear 834. Occasionally, it is configured to move away from the seventh transmission gear 837. When the sixth transmission gear 836 is moved away from the seventh transmission gear 837, the driving force from the fifth transmission gear 835 driven by the fourth transmission gear 834 is the seventh transmission gear 837 and the eighth transmission. It is not transmitted to the gear 838, and the drive of the drive roller 42 and the developing roller 52 of the belt device 40 is stopped.

The first drive gear 821 of the switching unit 82 has a first drive position (position shown in FIG. 4B) that meshes with the first transmission gear 831 and a second drive position (position shown in FIG. 4B) that meshes with the fifth transmission gear 835 (FIG. 4A). It is configured to be displaceable at the position shown in). The solenoid 822 is configured so that the first drive gear 821 can be switched between the first drive position and the second drive position. The first drive gear 821 is urged to the side displaced to the second drive position, and when the solenoid 822 is turned on, the position of the first drive gear 821 is switched to the first drive position against the urging force. When the solenoid 822 is turned off, the solenoid 822 is separated from the first drive gear 821, and the position of the first drive gear 821 is switched to the second drive position by the urging force.

That is, the first drive gear 821 is configured to be selectively connectable to one of the first drive row 83a and the second drive row 83b, and the solenoid 822 connects the first drive gear 821 to the first drive row. It is configured to be switchable between 83a and the second drive row 83b. Further, in the switching unit 82, the connection destination of the first drive gear 821 is switched between the first drive row 83a and the second drive row 83b by the solenoid 822, so that the driving force output from the motor 81 is output-coupled. It is possible to switch the rotation direction of 72 to be a forward rotation direction or a reverse rotation direction.

In the drive unit 8, the fourth transmission gear 834 is used for all the photoconductor drums 51 (first photoconductor drum 51-1, second photoconductor drum 51-2, third photoconductor drum 51-3, and the like. It can be connected to the output coupling 72 corresponding to the fourth photoconductor drum 51-4) via a driving force transmission mechanism. As a result, each photoconductor drum 51 can be driven by the fourth transmission gear 834. It is also possible to provide a switching unit 82, a first drive row 83a, and a second drive row 83b for each output coupling 72 corresponding to each photoconductor drum 51 to drive each output coupling 72.

As shown in FIG. 5, the image forming apparatus 1 has an ASIC (Application Specific Integrated Circuit) 90 that controls the driving of the image forming unit 5, the driving unit 8, the belt device 40, and the like. The ASIC 90 has a CPU 91. The CPU 91 is an example of a control unit that controls the drive of the drive unit and the belt device. The CPU 91 controls each unit such as the image forming unit 5, the driving unit 8, and the belt device 40 by executing programs for various processes based on the information input to the ASIC 90.

The image forming unit 5, the motor 81 and the solenoid 822 of the driving unit 8, the open / close sensor 94, the ROM 92, and the RAM 93 are connected to the ASIC 90. The ROM 92 stores a program executed by the CPU 91, various data, and the like. The RAM 93 is used as a work area when the CPU 91 executes a program. Further, various data and the like are temporarily stored in the RAM 93.

[Drive control of photoconductor drum]
The CPU 91 has a first mode in which the switching unit 82 is controlled so that the output coupling 72 rotates in the reverse rotation direction, and a second mode in which the switching unit 82 is controlled so that the output coupling 72 rotates in the forward rotation direction. It is configured so that the drive control of the photoconductor drum 51 having the above can be executed.

The drive control of the photoconductor drum 51 by the CPU 91 will be described. As shown in FIG. 6, in the drive control of the photoconductor drum 51, the CPU 91 first determines whether or not the front cover 22 has changed from the open state to the closed state based on the detection result of the open / close sensor 94. (Step S01).

When the CPU 91 determines in step S01 that the front cover 22 has not changed from the open state to the closed state (step S01: N), it determines that the front cover 22 has changed from the open state to the closed state. Step S01 is repeatedly executed until When the CPU 91 determines in step S01 that the front cover 22 has changed from the open state to the closed state (step S01: Y), the CPU 91 executes the first mode (step S02).

In the first mode of step S02, the CPU 91 rotates the motor 81 in the forward rotation direction and turns on the solenoid 822 to displace the first drive gear 821 to the first drive position. When the first drive gear 821 is displaced to the first drive position, it meshes with the first transmission gear 831, the driving force from the motor 81 is input to the first drive row 83a, and the output coupling 72 rotates in the reverse rotation direction. Further, when the first drive gear 821 is displaced to the first drive position, the sixth transmission gear 836 is separated from the seventh transmission gear 837, so that the drive roller 42 of the belt device 40 is stopped.

That is, in step S02, the CPU 91 executes the first mode of controlling the solenoid 822 of the switching unit 82 so that the output coupling 72 rotates in the reverse rotation direction while the belt device 40 is stopped.

If the front cover 22 is opened and then closed, it is conceivable that the photoconductor drum 51 has been removed from the device main body 2 and reattached. Further, the phase of the input coupling 71 in the reattached photoconductor drum 51 in the circumferential direction is deviated between the photoconductor drums 51 (for example, the phase of the input coupling 71 in the first photoconductor drum 51-1). , The phase of the input coupling 71 in the second photoconductor drum 51-2 is out of phase).

When the phase of the input coupling 71 is out of phase between the photoconductor drums 51, there is a photoconductor drum 51 in which the protrusion 72a of the output coupling 72 is not fitted in the concave groove 71a of the input coupling 71. However, by rotating the output coupling 72 in the reverse rotation direction, the protrusion 72a and the concave groove 71a can be fitted and the output coupling 72 and the input coupling 71 can be engaged with each other. In the first mode, the CPU 91 rotates in the opposite direction until the output coupling 72 makes at least one rotation so that all the output couplings 72 and the input couplings 71 mesh with each other.

In this case, the first drive row 83a has a torque limiter 839, and when the output coupling 72 and the input coupling 71 are fitted, the transmission of the driving force to the output coupling 72 is stopped, so that the output cup The rotation of the photoconductor drum 51 after the ring 72 and the input coupling 71 are engaged is suppressed.

Therefore, even if the output coupling 72 is rotated in the reverse rotation direction until all the output couplings 72 and the input couplings 71 are engaged with each other, the photoconductor drum 51 in which the output couplings 72 and the input couplings 71 are engaged with each other It is possible to keep the stopped state. Further, since the belt device 40 is stopped when the first mode is executed, there is no difference in peripheral speed between the transfer belt 41 of the belt device 40 and the photoconductor drum 51, and the photoconductor drum 51 and the transfer belt do not occur. It is possible to prevent the 41 from being damaged.

In particular, the first mode is executed after the CPU 91 determines that the front cover 22 has changed from the open state to the closed state, which is likely to be out of phase with the input coupling 71 between the photoconductor drums 51. Therefore, it is possible to effectively suppress the occurrence of damage to the photoconductor drum 51 and the transfer belt 41.

The CPU 91 executes the first mode in step S02 and then executes the second mode in step S03. In the second mode of step S03, the CPU 91 rotates the motor 81 in the forward rotation direction and turns off the solenoid 822 to displace the first drive gear 821 to the second drive position.

When the first drive gear 821 is displaced to the second drive position, it meshes with the fifth transmission gear 835, the driving force from the motor 81 is input to the second drive row 83b, and the output coupling 72 rotates in the forward rotation direction. Further, when the first drive gear 821 is displaced to the second drive position, the sixth transmission gear 836 is engaged with the seventh transmission gear 837, so that the drive roller 42 of the belt device 40 is driven.

That is, in step S03, the CPU 91 drives the belt device 40 and executes a second mode of controlling the solenoid 822 of the switching unit 82 so that the output coupling 72 rotates in the forward rotation direction. The CPU 91 drives the belt device 40, rotates the output coupling 72 in the forward rotation direction, and then controls the image forming unit 5 to form an image (step S04). In this way, by executing the second mode to drive the belt device 40 and rotate the output coupling 72 in the forward rotation direction, it is possible to form an image.

When the CPU 91 executes the first mode, the driving force from the motor 81 is input to the first transmission gear 831 via the first drive gear 821, and then accelerated and output from the second transmission gear 832. , Is transmitted to the output coupling 72. On the other hand, when the CPU 91 executes the second mode, the driving force from the motor 81 is input to the fifth transmission gear 835 via the first drive gear 821 and transmitted to the output coupling 72 without being accelerated. Will be done.

That is, the CPU 91 controls the drive unit 8 so that the rotation speed of the output coupling 72 when the first mode is executed is faster than the rotation speed when the second mode is executed. In this way, by increasing the rotation speed of the output coupling 72 when the first mode is executed, the time until the output coupling 72 and the input coupling 71 mesh with each other can be shortened, and the drive unit 8 can be driven. It is possible to shorten the time of the first printout from the start to the first image formation.

The drive unit 8 may be controlled so that the rotation speed of the output coupling 72 becomes faster when the first mode is executed than the rotation speed when the second mode is executed. For example, as shown in FIG. 7, the first transmission gear 831 is directly engaged with the third transmission gear 833 without passing through the second transmission gear 832 to increase the driving force input to the first transmission gear 831. It is possible to control the drive unit 8 so that the rotation speed of the motor 81 when the first mode is executed is faster than that when the second mode is executed, while transmitting to the third transmission gear 833.

In this way, by controlling the CPU 91, the motor 81 is driven so that the rotation speed during execution of the first mode is faster than the rotation speed during execution of the second mode, so that the gears constituting the first drive row 83a While reducing the number, it is possible to shorten the time from the start of driving of the driving unit 8 to the first printout.

In the present embodiment, the CPU 91 controls the drive unit 8 so that the rotation speed of the motor 81 when the first mode is executed is faster than the rotation speed of the motor 81 when the second mode is executed. It is also possible to control the drive unit 8 so that the rotation speed at the time of executing the mode is slower than the rotation speed at the time of executing the second mode. For example, under the control of the CPU 91, the motor 81 can be driven so that the rotation speed during execution of the first mode is slower than the rotation speed during execution of the second mode.

Here, when the output coupling 72 and the input coupling 71 are engaged with each other, if the rotation speed of the output coupling 72 is too fast, the protrusion 72a of the output coupling 72 fits into the concave groove 71a of the input coupling 71. It may be difficult to fit. In such a case, the protrusion 72a is easily fitted into the concave groove 71a by controlling the rotation speed of the motor 81 when the first mode is executed to be slower than the rotation speed when the second mode is executed. This makes it possible to smoothly engage the output coupling 72 and the input coupling 71 to appropriately form an image.

As described above, in the image forming apparatus 1, the CPU 91 can control the drive unit 8 so that the rotation speed of the output coupling 72 when the first mode is executed and the rotation speed when the second mode is executed are different. It is possible. As a result, it is possible to appropriately engage the output coupling 72 and the input coupling 71 according to the situation of the output coupling 72 and the input coupling 71. In this case, the rotation speed of the output coupling 72 is controlled by changing the rotation speed of the motor 81, or by switching between the first drive row 83a and the second drive row 83b for transmitting the driving force. can do.

Further, in the drive unit 8, the connection destination of the first drive gear 821 is switched between the first drive row 83a and the second drive row 83b by controlling the on / off of the solenoid 822 by the CPU 91. Therefore, it is possible to switch between the execution of the first mode and the execution of the second mode with high accuracy.

Further, the drive unit 8 has a lock mechanism 85 that regulates the rotation of the photoconductor drum 51 when the CPU 91 executes the first mode. As shown in FIG. 8, the locking mechanism 85 includes a gear portion 851 that meshes with the drum gear 54 of the photoconductor drum 51, a locked tooth portion 852 that is coaxially arranged with the gear portion 851 and that can rotate integrally, and a drum unit. It has a locking claw portion 853 supported by the frame portion 50a of the 50.

The gear portion 851 is configured to be rotatable as the photoconductor drum 51 rotates in the forward rotation direction. The locked tooth portion 852 has a plurality of locked teeth 852a arranged along the circumferential direction. The locked tooth 852a is an example of a tooth. The locked tooth 852a is obtained from the locked surface 852b located on the upstream side in the rotation direction of the locked tooth portion 852 when the photoconductor drum 51 is rotating in the forward rotation direction, and the locked surface 852b. Also has a sliding contact surface 852c located on the downstream side in the rotation direction.

The locking claw portion 853 is rotatably supported by the frame portion 50a around a rotation fulcrum 853a, and has a locking surface 853b that abuts on the locked surface 852b and a retracting surface that abuts on the sliding contact surface 852c. It has an 853c and a contact surface 853d that comes into contact with the frame portion 50a. The locking claw portion 853 is an example of a claw.

When the photoconductor drum 51 is rotated in the forward rotation direction, the gear portion 851 and the locked tooth portion 852 rotate in the clockwise direction in FIG. 8A and engage with the sliding contact surface 852c of the locked tooth 852a. The retracting surface 853c of the claw portion 853 comes into contact with the retracted surface 853c. The locking claw portion 853 can rotate about the rotation fulcrum 853a by pressing the contact surface 853d in the direction away from the frame portion 50a by the abutted locked teeth 852a.

As the locking claw portion 853 rotates, the sliding contact surface 852c and the retracting surface 853c are in sliding contact with each other, and the locking claw portion 853 does not lock the locked tooth portion 852. As a result, the locked tooth portion 852 can rotate. That is, the lock mechanism 85 is configured to allow the photoconductor drum 51 to rotate when the photoconductor drum 51 is rotated in the forward rotation direction.

On the other hand, when the photoconductor drum 51 is rotated in the reverse rotation direction, the gear portion 851 and the locked tooth portion 852 rotate in the counterclockwise direction in FIG. 8A, and the locked tooth 852a is locked. The surface 852b and the locking surface 853b of the locking claw portion 853 come into contact with each other. The locking claw portion 853 is pressed by the abutted locked teeth 852a in the direction in which the abutting surface 853d abuts on the frame portion 50a, and after the abutting surface 853d abuts on the frame portion 50a, it is rotated more times. It is regulated to move.

As a result, the locked tooth 852a is locked by the locking claw portion 853, and the rotation of the locked tooth portion 852 in the counterclockwise direction is restricted. That is, the lock mechanism 85 is configured to regulate the rotation of the photoconductor drum 51 when the photoconductor drum 51 is rotated in the reverse rotation direction.

In the image forming apparatus 1, when the first mode is executed by the CPU 91, when the output coupling 72 rotating in the reverse rotation direction meshes with the input coupling 71, the torque limiter 839 thereafter drives the driving force from the motor 81. Is stopped to be transmitted to the output coupling 72, so that the photoconductor drum 51 is not rotated by the driving force from the motor 81.

However, when the photoconductor drum 51 is about to be rotated in the reverse rotation direction due to other factors, the rotation of the photoconductor drum 51 can be restricted by the lock mechanism 85, so that the photoconductor drum 51 is being executed during the first mode. It is possible to prevent the photoconductor drum 51 and the belt device 40 from being damaged due to the unexpected rotation of the 51.

Further, the lock mechanism 85 locks the locked tooth portion 852 having the locked tooth 852a and the locked tooth 852a when the output coupling 72 rotates in the reverse rotation direction, and the output coupling 72 locks the locked tooth portion 852a. It is composed of a latch mechanism having a locking claw portion 853 that does not lock the locked tooth 852a when rotating in the forward rotation direction. Therefore, it is possible to effectively regulate the rotation of the photoconductor drum 51 with a simple configuration.

[Second Embodiment of Drive Unit]
The drive unit 8 that drives the output coupling 72 can also be configured as in the drive unit 108 shown in FIG. The drive unit 108 includes a motor 181, a switching unit 182, and a drive train 183. The motor 181 is an example of a drive source that outputs a driving force.

The switching unit 182 is a switching mechanism that switches the driving force output from the motor 181 so that the rotation direction of the output coupling 72 is the forward rotation direction or the reverse rotation direction for forming an image, and the driving force from the motor 181. It has a second drive gear 1821 to which is input, a first electromagnetic clutch 1822, and a second electromagnetic clutch 1823.

The drive train 183 is a transmission mechanism that transmits the driving force output from the motor 181 to the output coupling 72. The drive train 183 includes a first transmission gear 1831, a second transmission gear 1832 that is coaxially arranged with the first transmission gear 1831 and is rotatable integrally, and a third transmission gear 1833 that meshes with the second transmission gear 1832. It has a fourth transmission gear 1834 that meshes with a third transmission gear 1833. The first transmission gear 1831 meshes with the second drive gear 1821, and the fourth transmission gear 1834 meshes with the gear portion 72b of the output coupling 72.

Further, the drive train 183 includes a fifth transmission gear 1835 that meshes with the fourth transmission gear 1834, a sixth transmission gear 1836 that meshes with the fifth transmission gear 1835, and a seventh transmission gear 1837 that meshes with the sixth transmission gear 1836. It has an eighth transmission gear 1838 that meshes with a seventh transmission gear 1837. The fifth transmission gear 1835 meshes with the second drive gear 1821. The seventh transmission gear 1837 is connected to the drive roller 42 of the belt device 40, and the eighth transmission gear 1838 is connected to the developing roller 52.

The first transmission gear 1831, the second transmission gear 1832, the third transmission gear 1833, and the fourth transmission gear 1834 form the first drive row 183a. A second drive gear 1821 is connected to the first drive row 183a. As shown in FIG. 9B, in the first drive row 183a, the drive force from the motor 181 is input via the second drive gear 1821, and the input drive force can be transmitted to the output coupling 72. It is a column. The output coupling 72 rotates in the reverse rotation direction when the driving force from the motor 181 rotating in the forward rotation direction is transmitted by the first drive row 183a.

The second transmission gear 1832 is formed to have a diameter larger than that of the first transmission gear 1831, and the first transmission gear 1831 and the second transmission gear 1832 form a two-stage gear. As a result, the driving force input to the first transmission gear 1831 can be accelerated and output from the second transmission gear 1832. The third transmission gear 1833 has a torque limiter 1839, and when a torque of a predetermined value or more is applied to the output coupling 72 when the output coupling 72 is rotating in the reverse rotation direction, the third transmission gear 1833 The transmission of the driving force to the output coupling 72 is stopped by the torque limiter 1839. The torque limiter 1839 is provided in the first drive row 183a.

When the output coupling 72 is rotating in the reverse rotation direction, when the output coupling 72 and the input coupling 71 are fitted and can rotate integrally, the photoconductor drum 51 is attached to the output coupling 72. Although the torque it has is applied, in the present embodiment, when the torque possessed by the photoconductor drum 51 is applied to the output coupling 72, the torque limiter 1839 stops transmitting the driving force to the output coupling 72. It is set to do.

The fifth transmission gear 1835 and the fourth transmission gear 1834 constitute the second drive row 183b. A second drive gear 1821 is connected to the second drive row 183b. As shown in FIG. 9A, in the second drive row 183b, the drive force from the motor 181 is input via the second drive gear 1821, and the input drive force can be transmitted to the output coupling 72. It is a column. The output coupling 72 rotates in the forward rotation direction when the driving force from the motor 181 that rotates in the forward rotation direction is transmitted by the second drive row 83b.

The first electromagnetic clutch 1822 of the switching unit 182 is provided in the second transmission gear 1832 of the first drive row 183a. The first electromagnetic clutch 1822 is connected to the ASIC 90 and can be switched on and off under the control of the CPU 91. When the first electromagnetic clutch 1822 is turned on, the driving force from the second drive gear 1821 side is transmitted to the output coupling 72 side, and when it is turned off, the driving force from the second drive gear 1821 side is output to the output cup. It switches to the state where it is not transmitted to the ring 72 side.

The CPU 91 turns on the first electromagnetic clutch 1822 when the first mode is executed, switches to a state in which the driving force from the second drive gear 1821 side is transmitted to the output coupling 72 side, and the first mode is executed when the second mode is executed. The electromagnetic clutch 1822 is turned off to switch to a state in which the driving force from the second drive gear 1821 side is not transmitted to the output coupling 72 side.

When the first electromagnetic clutch 1822 is on, the driving force input to the first transmission gear 1831 is output from the second transmission gear 1832, and when the first electromagnetic clutch 1822 is off, the first transmission is performed. The driving force input to the gear 1831 is not output from the second transmission gear 1832.

The second electromagnetic clutch 1823 of the switching unit 82 is provided in the fifth transmission gear 1835 of the second drive row 183b. The second electromagnetic clutch 1823 is connected to the ASIC 90 and can be switched on and off under the control of the CPU 91. When the second electromagnetic clutch 1823 is turned on, the driving force from the second driving gear 1821 side is transmitted to the output coupling 72 side, and when it is turned off, the driving force from the second driving gear 1821 side is output. It switches to a state where it is not transmitted to the coupling 72 side.

The CPU 91 turns off the second electromagnetic clutch 1823 when the first mode is executed, switches to a state in which the driving force from the second drive gear 1821 side is not transmitted to the output coupling 72 side, and second when the second mode is executed. The electromagnetic clutch 1823 is turned on to switch to a state in which the driving force from the second drive gear 1821 side is transmitted to the output coupling 72 side.

When the second electromagnetic clutch 1823 is on, the fifth transmission gear 1835 outputs the driving force input from the second drive gear 1821 to the fourth transmission gear 1834, and the second electromagnetic clutch 1823 is turned off. When, the fifth transmission gear 1835 does not output the driving force input from the second drive gear 1821 to the fourth transmission gear 1834.

In this way, when the first mode is executed, the CPU 91 turns on the first electromagnetic clutch 1822 to switch to a state in which the driving force from the second drive gear 1821 side is transmitted to the output coupling 72 side, and the second electromagnetic clutch is transmitted. The clutch 1823 is disengaged to switch to a state in which the driving force from the second drive gear 1821 side is not transmitted to the output coupling 72 side. As a result, when the first mode is executed, the driving force from the motor 81 is transmitted to the output coupling 72 by the first driving row 183a, and the output coupling 72 rotates in the reverse rotation direction. In this case, the fifth transmission gear 1835 is driven by the fourth transmission gear 1834.

Further, when the second mode is executed, the CPU 91 turns off the first electromagnetic clutch 1822 to switch to a state in which the driving force from the second drive gear 1821 side is not transmitted to the output coupling 72 side, and the second electromagnetic clutch 1823. Is turned on to switch to a state in which the driving force from the second drive gear 1821 side is transmitted to the output coupling 72 side. As a result, when the second mode is executed, the driving force from the motor 81 is transmitted to the output coupling 72 by the second drive row 183a, and the output coupling 72 rotates in the forward rotation direction.

The sixth transmission gear 1836, the seventh transmission gear 1837, and the eighth transmission gear 1838 constitute the third drive row 183c. As shown in FIG. 9A, in the sixth transmission gear 1836, the second electromagnetic clutch 1823 is turned on, and the fifth transmission gear 1835 receives the driving force input from the second drive gear 1821 to the fourth transmission gear 1834. It is configured to move to a position where it meshes with the 7th transmission gear 1837 when it is outputting to.

When the sixth transmission gear 1836 is moved to a position where it meshes with the seventh transmission gear 1837, the driving force from the fifth transmission gear 1835 driven by the second drive gear 1821 is applied to the seventh transmission gear 1837 and the eighth transmission gear. It is transmitted to 1838, and the driving roller 42 and the developing roller 52 of the belt device 40 are driven.

As shown in FIG. 9B, in the sixth transmission gear 1836, the second electromagnetic clutch 1823 is disengaged, and the fifth transmission gear 1835 applies the driving force input from the second drive gear 1821 to the fourth transmission gear 1834. When the fifth transmission gear 1835 is driven by the fourth transmission gear 1834, it is configured to move to a position away from the seventh transmission gear 1837. When the sixth transmission gear 1836 is moved away from the seventh transmission gear 1837, the driving force from the fifth transmission gear 1835 driven by the fourth transmission gear 1834 is the seventh transmission gear 1837 and the eighth transmission. It is not transmitted to the gear 1838, and the drive of the drive roller 42 and the developing roller 52 of the belt device 40 is stopped.

As described above, in the drive unit 108, the switching unit 182 is configured by using the first electromagnetic clutch 1822 and the second electromagnetic clutch 1823, and the first electromagnetic clutch 1822 and the second electromagnetic clutch 1823 are turned on and off by the CPU 91. By switching by control, the transmission destination of the driving force from the second driving gear 1821 is configured to be switched between the first driving row 183a and the second driving row 183b.

As a result, the driving force from the second drive gear 1821 is transmitted to the output coupling 72 via the first drive row 183a, the output coupling 72 is rotated in the reverse rotation direction, the execution of the first mode, and the second drive. The driving force from the gear 1821 is transmitted to the output coupling 72 via the second drive row 183b, and the execution of the second mode in which the output coupling 72 is rotated in the forward rotation direction can be switched with high accuracy. ing.

In the drive unit 108, the fourth transmission gear 1834 can be connected to the output couplings 72 corresponding to all the photoconductor drums 51 via the drive force transmission mechanism. As a result, each photoconductor drum 51 can be driven by the fourth transmission gear 1834.
It is also possible to provide a switching unit 182, a first drive row 183a, and a second drive row 183b for each output coupling 72 corresponding to each photoconductor drum 51 to drive each output coupling 72.

The drive unit 108 has a lock mechanism 85 that regulates the rotation of the photoconductor drum 51 when the CPU 91 executes the first mode.

Further, also in the drive unit 108, when the CPU 91 executes the first mode, the driving force from the motor 181 is accelerated and output from the second transmission gear 1832, and the output coupling 72 is executed in the second mode. It is configured so that the rotation speed at the time of executing the first mode is faster than the rotation speed. This makes it possible to shorten the time of the first printout from the start of driving the drive unit 108 to the first image formation.

Further, the drive unit 108 may be controlled so that the rotation speed of the output coupling 72 becomes faster when the first mode is executed than the rotation speed when the second mode is executed. it can.

For example, as shown in FIG. 10, the first transmission gear 1831 is directly engaged with the third transmission gear 1833 without passing through the second transmission gear 1832 to increase the driving force input to the first transmission gear 1831. It is possible to control the drive unit 108 so that the rotation speed of the motor 181 when the first mode is executed is faster than that when the second mode is executed, while transmitting to the third transmission gear 1833. In this case, the first electromagnetic clutch 1822 can be provided, for example, in the first transmission gear 1831. As a result, it is possible to shorten the time from the start of driving of the driving unit 108 to the first printout while reducing the number of gears constituting the first driving row 183a.

[Third Embodiment of the drive unit]
The drive unit 8 that drives the output coupling 72 can also be configured as in the drive unit 208 shown in FIG. The drive unit 208 has a switching unit 282 and a drive train 283.

The switching unit 282 has a motor 2821 capable of forward / reverse rotation and a pendulum gear 2822 to which a driving force from the motor 2821 is input. The motor 2821 is an example of a drive source that outputs a driving force. The switching unit 282 is a switching mechanism that switches the driving force output from the motor 2821 so that the rotation direction of the output coupling 72 is the forward rotation direction or the reverse rotation direction for forming an image.

The drive train 283 is a transmission mechanism that transmits the driving force output from the motor 2821 to the output coupling 72. The drive train 283 has a first transmission gear 2831, a second transmission gear 2832 coaxially arranged with the first transmission gear 2831 and rotatable integrally, and a third transmission gear 2833 that meshes with the second transmission gear 2832. Have. The first transmission gear 2831 is meshable with the pendulum gear 2822, and the third transmission gear 2833 is meshed with the gear portion 72b of the output coupling 72.

Further, the drive train 283 includes a fourth transmission gear 2834 that meshes with the third transmission gear 833, a fifth transmission gear 2835 that can mesh with the fourth transmission gear 2834, and a sixth transmission gear 2836 that meshes with the fifth transmission gear 2835. It has a seventh transmission gear 2837 that meshes with the sixth transmission gear 2836. The fourth transmission gear 2834 can mesh with the pendulum gear 2822. The sixth transmission gear 2836 is connected to the drive roller 42 of the belt device 40, and the seventh transmission gear 2837 is connected to the developing roller 52.

The first transmission gear 2831, the second transmission gear 2832, and the third transmission gear 2833 form the first drive row 283a. As shown in FIG. 11B, in the first drive row 283a, the driving force from the motor 281 is input when the pendulum gear 2822 is engaged with the first transmission gear 2831, and the input driving force is output to the output cup. It is a drive train transmitted to the ring 72. When the driving force from the motor 281 rotating in the reverse rotation direction is transmitted to the output coupling 72 by the first drive row 283a, the output coupling 72 rotates in the reverse rotation direction.

The second transmission gear 2832 is formed to have a diameter larger than that of the first transmission gear 2831, and the first transmission gear 2831 and the second transmission gear 2832 form a two-stage gear. As a result, the driving force input to the first transmission gear 2831 is accelerated and output from the second transmission gear 2832. The first drive row 283a has a torque limiter 2839 between the first transmission gear 2831 and the second transmission gear 2832, and the output coupling 72 is rotated when the output coupling 72 is rotating in the reverse rotation direction. When a torque of a predetermined value or more is applied to the torque limiter 2839, the transmission of the driving force from the second transmission gear 2832 to the output coupling 72 is stopped by the torque limiter 2839. The torque limiter 2839 is provided in the first drive row 283a.

When the output coupling 72 is rotating in the reverse rotation direction, when the output coupling 72 and the input coupling 71 are fitted and can rotate integrally, the photoconductor drum 51 is attached to the output coupling 72. Although the torque it has is applied, in the present embodiment, when the torque possessed by the photoconductor drum 51 is applied to the output coupling 72, the torque limiter 2839 stops transmitting the driving force to the output coupling 72. It is set to do.

The fourth transmission gear 2834 and the third transmission gear 2833 form the second drive row 283b. As shown in FIG. 11A, in the second drive row 283b, the driving force from the motor 2821 is input when the fourth transmission gear 2834 is engaged with the pendulum gear 2822, and the input driving force is output to the output cup. It is a drive train transmitted to the ring 72. When the driving force from the motor 281 rotating in the forward rotation direction is transmitted to the output coupling 72 by the second drive row 283b, the output coupling 72 rotates in the forward rotation direction.

The fifth transmission gear 2835, the sixth transmission gear 2836, and the seventh transmission gear 2837 form a third drive row 283c. As shown in FIG. 11A, the fourth transmission gear 2834 is configured to mesh with the pendulum gear 2822 and move to a position where it meshes with the fifth transmission gear 2835 when driven by the pendulum gear 2822. ..

When the 4th transmission gear 2834 is moved to a position where it meshes with the 5th transmission gear 2835, the driving force from the 4th transmission gear 2834 driven by the pendulum gear 2822 is transmitted to the 6th transmission gear 2835 via the 5th transmission gear 2835. It is transmitted to the gear 2836 and the seventh transmission gear 2837, and the drive roller 42 and the developing roller 52 of the belt device 40 are driven.

As shown in FIG. 11B, the fourth transmission gear 2834 does not mesh with the pendulum gear 2822 and moves to a position away from the fifth transmission gear 2835 when driven by the third transmission gear 2833. It is configured as follows. When the fourth transmission gear 2834 is moved away from the fifth transmission gear 2835, the driving force from the fourth transmission gear 2834 driven by the third transmission gear 2833 is the sixth transmission gear 2836 and the seventh transmission. It is not transmitted to the gear 2837, and the drive of the drive roller 42 and the developing roller 52 of the belt device 40 is stopped.

The pendulum gear 2822 of the switching unit 282 has a first position (position shown in FIG. 11B) that meshes with the first transmission gear 2831 and a second position (position shown in FIG. 11A) that meshes with the fourth transmission gear 2834. ) And is configured to be displaceable. The pendulum gear 2822 is displaced to the first position by the driving force from the motor 2821 when the motor 2821 rotates in the forward rotation direction, and is displaced to the second position by the driving force from the motor 2821 when the motor 2821 rotates in the reverse rotation direction. ..

That is, the pendulum gear 2822 receives the driving force from the motor 2821 and is connected to the first drive row 283a and the second drive row 283b corresponding to the rotation direction of the motor 2821. It is configured to be displaced between two positions. Further, in the switching unit 282, by switching the rotation direction of the motor 2821 between the forward rotation direction and the reverse rotation direction, the driving force output from the motor 2821 is changed to the forward rotation direction or the reverse rotation direction of the output coupling 72. It is possible to switch to the direction of rotation.

The motor 2821 is connected to the ASIC 90, and the CPU 91 rotates the motor 2821 in the reverse rotation direction when the first mode is executed. As a result, when the first mode is executed, the pendulum gear 2822 is displaced to the first position, the driving force from the motor 2821 is transmitted to the output coupling 72 by the first drive row 283a, and the output coupling 72 It rotates in the reverse rotation direction.

Further, the CPU 91 rotates the motor 2821 in the forward rotation direction when the second mode is executed. As a result, when the second mode is executed, the pendulum gear 2822 is displaced to the second position, the driving force from the motor 2821 is transmitted to the output coupling 72 by the second drive row 283b, and the output coupling 72 is executed. Rotates in the forward rotation direction.

As described above, in the drive unit 208, the switching unit 282 is configured by using the motor 2821 capable of forward / reverse rotation and the pendulum gear 2822 that is displaced between the first position and the second position, and the pendulum gear 2822. By switching between the first position and the second position of the motor 2821 according to the rotation direction of the motor 2821, the transmission destination of the driving force from the motor 2821 is switched between the first drive row 283a and the second drive row 283b. are doing.

As a result, the driving force from the motor 2821 is transmitted to the output coupling 72 via the first driving row 283a to execute the first mode in which the output coupling 72 is rotated in the reverse rotation direction, and the driving force from the motor 2821. Is transmitted to the output coupling 72 via the second drive row 283b, and the execution of the second mode in which the output coupling 72 is rotated in the forward rotation direction can be switched with high accuracy.

In the drive unit 208, the third transmission gear 2833 can be connected to the output coupling 72 corresponding to all the photoconductor drums 51 via the drive force transmission mechanism. As a result, each photoconductor drum 51 can be driven by the third transmission gear 2833. It is also possible to provide the switching unit 282, the first drive row 283a, and the second drive row 283b for each output coupling 72 corresponding to each photoconductor drum 51 to drive each output coupling 72.

The drive unit 208 has a lock mechanism 85 that regulates the rotation of the photoconductor drum 51 when the CPU 91 executes the first mode.

Further, also in the drive unit 208, when the CPU 91 executes the first mode, the driving force from the motor 2821 is accelerated and output from the second transmission gear 2832, and the output coupling 72 is executed in the second mode. It is configured so that the rotation speed at the time of executing the first mode is faster than the rotation speed. This makes it possible to shorten the time of the first printout from the start of driving the drive unit 208 to the first image formation.

Further, as a configuration for controlling the drive unit 208 so that the rotation speed of the output coupling 72 in the execution of the first mode is faster than the rotation speed in the execution of the second mode, the following configuration may be used. it can.

For example, as shown in FIG. 12, the first transmission gear 2831 is directly engaged with the third transmission gear 2833 without passing through the second transmission gear 2832 to increase the driving force input to the first transmission gear 2831. It is possible to control the drive unit 208 so that the rotation speed of the motor 2821 when the first mode is executed is faster than that when the second mode is executed, while transmitting to the third transmission gear 2833. As a result, it is possible to shorten the time from the start of driving of the driving unit 208 to the first printout while reducing the number of gears constituting the first driving row 283a.

[Second Embodiment of the apparatus main body]
The apparatus main body 2 may have the following configuration in addition to the configuration in which the opening 2A is formed on the front surface 21 and the front cover 22 for opening and closing the opening 2A.

The apparatus main body 2 shown in FIG. 13A has an opening 2B formed on the upper surface 23 and has a top cover 24 for opening and closing the opening 2B. The top cover 24 is an example of a cover whose opening can be opened and closed. The upper surface cover 24 is configured to be rotatable around a rotation shaft portion 24a at the rear end portion, and has a detector 24b protruding downward at the front end portion. The device main body 2 has an open / close sensor 95 that detects the open / close of the top cover 24. The open / close sensor 95 is arranged at the upper end and the front end of the device main body 2. The open / close sensor 95 is connected to the ASIC 90.

The open / close sensor 95 detects the detector 24b when the top cover 24 is closed and closes the opening 2B, and detects that the top cover 24 is closed by detecting the detector 24b. Further, the open / close sensor 95 does not detect the detector 24b when the top cover 24 is open and the opening 2B is open, and detects that the top cover 24 is open by not detecting the detector 24b. .. In the present embodiment, the photoconductor drum 51 is configured to be removable from the device main body 2 via the opening 2B.

[Third Embodiment of the apparatus main body]
The device main body 2 can be further configured as follows.

The apparatus main body 2 shown in FIG. 13B has an opening 2C formed on the right side surface 25 and a right side cover 26 for opening and closing the opening 2C. The right side cover 26 is an example of a cover whose opening can be opened and closed. The right side cover 26 is configured to be rotatable around a rotation shaft portion 26a at the lower end portion, and has a detector 26b protruding to the left at the upper end portion. The device main body 2 has an open / close sensor 96 that detects the open / close of the right side cover 26. The open / close sensor 96 is arranged at the upper end and the rear end of the device main body 2. The open / close sensor 96 is connected to the ASIC 90.

The open / close sensor 96 detects the detector 26b when the right side cover 26 is closed and closes the opening 2C, and detects that the right side cover 26 is closed by detecting the detector 26b. Further, the open / close sensor 96 does not detect the detector 26b when the right side cover 26 is opened and the opening 2C is opened, and the right side cover 26 is opened by not detecting the detector 26b. Detect.

In the present embodiment, the photoconductor drum 51 is configured to be detachable from the device main body 2 via the opening 2C. Further, the apparatus main body 2 may have an opening formed on the left side surface and a cover capable of opening and closing the opening on the left side surface.

[Effects in this embodiment]
In the present embodiment, the image forming apparatus 1 is configured as follows.
That is, the image forming apparatus 1 is an electrophotographic image forming apparatus, and is an apparatus main body 2, a photoconductor drum 51 (first photoconductor drum 51-1 and a second photoconductor drum 51-2), and a belt. It includes a device 40, an output coupling 72, a drive unit 8, a torque limiter 839, and a CPU 91. The photoconductor drum 51 has an input coupling 71 that is detachable from the device main body 2 and to which a driving force is input. The belt device 40 is arranged to face the photoconductor drum 51. The output coupling 72 is provided in the device main body 2 and transmits a driving force to the input coupling 71. The drive unit 8 transfers the driving force output from the motor 81 to the output coupling 72, the motor 81 that outputs the driving force, and the drive train 83 that transmits the driving force output from the motor 81 to the output coupling 72. It has a switching unit 82 that switches the rotation direction so that it is in the forward rotation direction or the reverse rotation direction in which the image is formed. The torque limiter 839 is provided in the drive row 83, and when the output coupling 72 is rotating in the reverse rotation direction, if a torque of a predetermined value or more is applied to the output coupling 72, the torque limiter 839 is transmitted to the output coupling 72 of the motor 81. To stop. The CPU 91 controls the drive of the drive unit 8 and the belt device 40. The CPU 91 drives the belt device 40 in the first mode in which the switching unit 82 is controlled so that the output coupling 72 rotates in the reverse rotation direction while the belt device 40 is stopped, and the output coupling 72 is positive. A second mode for controlling the switching unit 82 so as to rotate in the rotation direction is executed.

With such a configuration, by rotating the output coupling 72 in the reverse rotation direction when the first mode is executed, even if the phase of the input coupling 71 is out of phase between the photoconductor drums 51, the output coupling 72 is input. It can be engaged with the coupling 71. In this case, since the drive train 83 has a torque limiter 839 capable of stopping the transmission of the driving force when the output coupling 72 is rotating in the reverse rotation direction, all the drive trains 83 are stopped with the belt device 40 stopped. The engaged coupling 7 can be stopped until the output coupling 72 and the input coupling 71 are engaged. As a result, there is no difference in peripheral speed between the transfer belt 41 of the belt device 40 and the photoconductor drum 51, and it is possible to prevent the photoconductor drum 51 and the transfer belt 41 from being damaged. Further, when the second mode is executed, the image can be formed by driving the belt device 40 and rotating the output coupling 72 in the forward rotation direction.

Further, the apparatus main body 2 has a front surface 21 on which the opening 2A is formed, a front cover 22 capable of opening and closing the opening 2A, and an opening / closing sensor 94 for detecting the opening / closing of the front cover 22. The photoconductor drum 51 can be attached and detached via the apparatus, and the CPU 91 executes the first mode after determining that the front cover 22 has changed from the open state to the closed state based on the detection result of the open / close sensor 94.

In this way, by executing the first mode after the front cover 22 has changed from the open state to the closed state, which is likely to be out of phase with the input coupling 71 between the photoconductor drums 51, It is possible to effectively suppress the occurrence of damage to the photoconductor drum 51 and the transfer belt 41.

Further, it has a lock mechanism 85 that regulates the rotation of the photoconductor drum 51 when the first mode is executed.

As a result, when the photoconductor drum 51 is about to be rotated in the reverse rotation direction, the rotation of the photoconductor drum 51 can be restricted by the lock mechanism 85, so that the photoconductor drum 51 is unexpectedly rotated during the execution of the first mode. It is possible to prevent the photoconductor drum 51 and the belt device 40 from being damaged by the rotation.

Further, the CPU 91 controls the drive unit 8 so that the rotation speed of the output coupling 72 when the first mode is executed is different from the rotation speed when the second mode is executed.

Thereby, the output coupling 72 and the input coupling 71 can be appropriately engaged with each other depending on the situation of the output coupling 72 and the input coupling 71.

Further, the CPU 91 controls the drive unit 8 so that the rotation speed of the output coupling 72 when the first mode is executed is faster than the rotation speed when the output coupling 72 is executed in the second mode.

As a result, the time required to engage the output coupling 72 and the input coupling 71 can be shortened, and the time required for the first printout from the start of driving the drive unit 8 to the first image formation can be shortened. It is possible.

Further, the CPU 91 controls the drive unit 8 so that the rotation speed of the output coupling 72 when the first mode is executed is slower than the rotation speed when the output coupling 72 is executed in the second mode.

As a result, the protrusion 72a of the output coupling 72 can be easily fitted into the concave groove 71a of the input coupling 71, and the output coupling 72 and the input coupling 71 are smoothly meshed with each other to obtain an appropriate image. The formation can be performed.

Further, the output coupling 72 is a one-phase coupling.

As a result, the phase in which the output coupling 72 and the input coupling 71 corresponding to one photoconductor drum 51 (for example, the first photoconductor drum 51-1) mesh with each other and the other photoconductor drum 51 (for example, the second photoconductor drum 51) The phase at which the output coupling 72 corresponding to the photoconductor drum 51-2) and the input coupling 71 mesh with each other can always be matched. Therefore, it is easy to correct the dimensional error of the photoconductor drum 51, and it is possible to reduce the color shift of each color at the time of image formation.

Further, the lock mechanism 85 locks the locked tooth 852a and the locked tooth 852a when the output coupling 72 rotates in the reverse rotation direction, and when the output coupling 72 rotates in the forward rotation direction. It is a latch mechanism having a locking claw portion 853 that does not lock the locked tooth 852a.

Thereby, it is possible to effectively regulate the rotation of the photoconductor drum 51 with a simple configuration.

Further, the drive train 83 has a first drive row 83a to which a driving force is input when the first mode is executed, and a second drive row 83b to which a driving force is input when the second mode is executed. The 82 is connected to the first drive gear 821 and the connection destination of the first drive gear 821, to which the driving force from the motor 81 is input and which can be selectively connected to one of the first drive row 83a and the second drive row 83b. It has a solenoid 822 that switches between the first drive row 83a and the second drive row 83b, and the torque limiter 839 is provided in the first drive row 83a.

In this way, by switching the connection destination of the first drive gear 821 by the solenoid 822, it is possible to switch between the execution of the first mode and the execution of the second mode with high accuracy.

Further, the drive row 183 has a first drive row 183a to which a driving force is input when the first mode is executed, and a second drive row 183b to which a driving force is input when the second mode is executed. The 182 is provided in the second drive gear 1821 connected to the first drive row 183a and the second drive row 183b and the first drive row 183a to which the driving force from the motor 181 is input, and is provided in the first drive row 183a when the first mode is executed. The first electromagnetic clutch 1822 that transmits the driving force from the second drive gear 1821 side to the output coupling 72 side and does not transmit the driving force from the second drive gear 1821 side to the output coupling 72 side when the second mode is executed. And is provided in the second drive row 183b, the driving force from the second drive gear 1821 side is transmitted to the output coupling 72 side when the second mode is executed, and from the second drive gear 1821 side when the first mode is executed. The torque limiter 1839 is provided in the first drive row 183a, and has a second electromagnetic clutch 1823 that does not transmit the driving force of the above to the output coupling 72 side.

As a result, by switching the transmission state of the driving force of the first electromagnetic clutch 1822 and the second electromagnetic clutch 1823, it is possible to switch between the execution of the first mode and the execution of the second mode with high accuracy.

Further, the drive row 283 has a first drive row 283a to which a driving force is input when the first mode is executed, and a second drive row 283b to which a driving force is input when the second mode is executed. The 282 is a motor 2821 capable of forward / reverse rotation, and a driving force from the motor 2821 is input to the first position and the second driving row 283b connected to the first driving row 283a corresponding to the rotation direction of the motor 2821. It has a pendulum gear 2822 that is displaced from the second position to be connected, and a torque limiter 2839 is provided in the first drive row 283a.

As a result, by switching the rotation direction of the motor 2821, it is possible to switch between the execution of the first mode and the execution of the second mode with high accuracy.

1 Image forming device 2 Device body 2A Opening 5 Image forming part 8 Drive section 21 Front surface 22 Front cover 40 Belt device 41 Transfer belt 51 Photoreceptor drum 51-1 First photoconductor drum 51-2 Second photoconductor drum 71 Input Coupling 71a Concave groove 72 Output coupling 72a Protrusion 81, 181, 2821 Motor 82 Switching part 83, 183, 283 Drive row 83a, 183a, 283a First drive row 83b, 183b, 283b Second drive row 85 Lock mechanism 91 CPU
94 Open / close sensor 821 1st drive gear 822 Solenoid 839, 1839, 2839 Torque limiter 852a Locked tooth 853 Locking claw 1821 2nd drive gear 1822 1st electromagnetic clutch 1823 2nd electromagnetic clutch 2822 Pendant gear

Claims (11)

It is an electrophotographic image forming device, and the device body and
A first photoconductor drum having a first input coupling that is removable from the device body and to which a driving force is input, and a second input cup that is removable from the device body and to which a driving force is input. A second photoconductor drum with a ring and
A belt device arranged to face the first photoconductor drum and the second photoconductor drum, and
A first output coupling provided in the apparatus main body and transmitting a driving force to the first input coupling, and a second output coupling provided in the apparatus main body and transmitting a driving force to the second input coupling.
A drive source that outputs the drive force, a drive train that transmits the drive force output from the drive source to the first output coupling and the second output coupling, and a drive force output from the drive source. A drive unit having a switching unit for switching the rotation direction of the first output coupling and the second output coupling to be a forward rotation direction or a reverse rotation direction for forming an image.
When the first output coupling and the second output coupling are rotating in the reverse rotation direction provided in the drive train, the first output coupling and the second output coupling have a predetermined value or more. A torque limiter that stops the transmission of the driving force to the first output coupling and the second output coupling when torque is applied.
The drive unit and the control unit that controls the drive of the belt device are provided.
The control unit
A first mode in which the switching unit is controlled so that the first output coupling and the second output coupling rotate in the reverse rotation direction while the belt device is stopped.
An image formation characterized by driving the belt device and executing a second mode of controlling the switching unit so that the first output coupling and the second output coupling rotate in the forward rotation direction. apparatus. The device body
It has an opening surface on which an opening is formed, a cover capable of opening and closing the opening, and a sensor for detecting the opening and closing of the cover.
The first photoconductor drum and the second photoconductor drum can be attached and detached through the opening.
The image according to claim 1, wherein the control unit executes the first mode after determining that the cover has changed from the open state to the closed state based on the detection result of the sensor. Forming device. The image forming apparatus according to claim 1 or 2, further comprising a locking mechanism for restricting the rotation of the first photoconductor drum and the second photoconductor drum when the first mode is executed. The control unit controls the drive unit so that the rotation speed of the first output coupling and the second output coupling during execution of the first mode differs from the rotation speed of the second output coupling during execution of the second mode. The image forming apparatus according to any one of claims 1 to 3, wherein the image forming apparatus is used. The control unit sets the drive unit so that the rotation speed of the first output coupling and the second output coupling during the execution of the first mode is faster than the rotation speed of the first output coupling and the second output coupling during the execution of the second mode. The image forming apparatus according to claim 4, wherein the image forming apparatus is controlled. The control unit sets the drive unit so that the rotation speed of the first output coupling and the second output coupling during execution of the first mode is slower than the rotation speed of the first output coupling during execution of the second mode. The image forming apparatus according to claim 4, wherein the image forming apparatus is controlled. The image forming apparatus according to any one of claims 1 to 6, wherein the first output coupling and the second output coupling are one-phase couplings. The locking mechanism locks the tooth with the tooth when the first output coupling and the second output coupling rotate in the reverse rotation direction, and the first output coupling and the second output coupling. The image forming apparatus according to claim 3, further comprising a latch mechanism having a claw that does not lock the teeth when the tooth is rotated in the forward rotation direction. The driving train has a first driving row in which the driving force is input when the first mode is executed, and a second driving row in which the driving force is input when the second mode is executed.
The switching unit is connected to a first drive gear to which a drive force from the drive source is input and which can be selectively connected to one of the first drive row and the second drive row, and the first drive gear. It has a solenoid that switches the tip between the first drive row and the second drive row.
The image forming apparatus according to any one of claims 1 to 8, wherein the torque limiter is provided in the first drive row. The driving train has a first driving row in which the driving force is input when the first mode is executed, and a second driving row in which the driving force is input when the second mode is executed.
The switching unit is
A driving force from the driving source is input, and a second driving gear connected to the first driving row and the second driving row, and
Provided in the first drive row, when the first mode is executed, the driving force from the second drive gear side is transmitted to the first output coupling side and the second output coupling side, and the second mode The first electromagnetic clutch that does not transmit the driving force from the second drive gear side to the first output coupling side and the second output coupling side at the time of execution of
Provided in the second drive row, when the second mode is executed, the driving force from the second drive gear side is transmitted to the first output coupling side and the second output coupling side, and the first mode Has a second electromagnetic clutch that does not transmit the driving force from the second drive gear side to the first output coupling side and the second output coupling side at the time of execution.
The image forming apparatus according to any one of claims 1 to 8, wherein the torque limiter is provided in the first drive row. The driving train has a first driving row in which the driving force is input when the first mode is executed, and a second driving row in which the driving force is input when the second mode is executed.
The switching unit has the drive source capable of forward and reverse rotation, the first position where the drive force from the drive source is input, and the first position connected to the first drive row corresponding to the rotation direction of the drive source. It has a pendulum gear that displaces with a second position connected to the second drive train.
The image forming apparatus according to any one of claims 1 to 8, wherein the torque limiter is provided in the first drive row.

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