JP6547859B2 - DRIVE TRANSMISSION DEVICE AND IMAGE FORMING APPARATUS PROVIDED WITH THE DRIVE TRANSMISSION DEVICE - Google Patents

Description

  The present invention relates to a drive transmission device capable of switching between normal rotation and reverse rotation of output rotation, and an image forming apparatus provided with the drive transmission device.

2. Description of the Related Art Conventionally, there is known a drive transmission device which receives an output rotation from one motor and transmits the rotation to an output shaft in a forward and reverse direction (e.g., Patent Document 1).
In this prior art, two paths are provided as drive transmission paths from the drive input gear engaged with the gear to which the rotation is input from the motor to the drive output gear for transmitting the rotation to the driven body.
The first path is a path transmitted from the drive input gear to the drive output gear via a positive rotation clutch that is engaged at the time of normal rotation output and released at the time of reverse rotation output.
The second path is a path transmitted from the drive input gear, through the counter gear, to the drive output gear through the reverse rotation clutch which is released at the time of normal rotation output and released at the time of reverse rotation output.
As described above, when the number of gears interposed is different between the first path and the second path, rotation of the drive output gear can be performed while driving one motor in a single rotation direction. It can be selectively transmitted.

However, in the above-mentioned prior art, the counter gear and the input gears of both clutches are additionally provided in the outer diameter direction of the drive input gear, and the output gears of both clutches are additionally provided in the outer diameter direction. Has a drive output gear.
As described above, since the drive input gear has a structure in which two gears consisting of a plurality of gears are arranged in the outer diameter direction of the rotation shaft, there is a problem that the occupied space in the outer diameter direction of the device becomes large. It was

  The present invention has been made focusing on the above-described conventional problems, and provides a drive transmission device capable of reducing the space occupied in the outer radial direction of the rotation shaft, and an image forming apparatus provided with the drive transmission device. It is in.

In order to achieve the above object, the present invention is
A first rotation axis,
A first rotating body and a third rotating body provided on the first rotation shaft,
A first drive switching unit that switches between drive transmission and drive cutoff between the first rotation shaft and the first rotation body, or between the first rotation shaft and the third rotation body;
A second rotation axis,
A second rotating body and a fourth rotating body provided on the second rotation shaft,
A second drive switching unit that switches between drive transmission and drive cutoff between the second rotation shaft and the second rotation body or between the second rotation shaft and the fourth rotation body;
A drive transmission rotating body drivingly connected to the first rotating body or the second rotating body;
Drive transmission device comprising
The first rotating body and the second rotating body are drivingly connected to rotate in opposite directions to each other, while the third rotating body and the fourth rotating body are driven to rotate in the same direction. Are linked and
The drive transmission device is characterized in that the rotation directions of the third and fourth rotating bodies are switched in the forward and reverse directions in accordance with the switching operation of the first drive switching unit and the second drive switching unit. And

According to the drive transmission device of the present invention, drive is transmitted to the output side rotary shaft on the output side only from the input side rotary shaft, and the input side drive switching unit and the output side drive switching unit are shafts of both rotary shafts. It was made to provide between directions.
Therefore, the number of gears meshing in the radial direction is reduced to reduce the occupied space in the outer diameter direction, as compared with the case where the rotational direction of the drive transmission is switched by the difference in the number of gears arranged in the radial direction. Is possible.

FIG. 1 is a configuration explanatory view showing a schematic configuration of an image forming apparatus to which the drive transmission apparatus of the embodiment 1 of the present invention is applied. FIG. 2 is an explanatory view showing a drive transmission state at the time of normal rotation output of the drive transmission device of the embodiment 1, wherein (a) shows a state viewed from the direction along the rotation axis, and (b) shows the rotation axis The state as viewed from the radial direction is shown. FIG. 3 is an explanatory view showing a drive transmission state at the time of reverse output of the drive transmission device according to the first embodiment, where (a) shows a state viewed from the direction along the rotation axis, and (b) shows the diameter of the rotation axis It shows the state seen from the direction. FIG. 4 is an explanatory view showing a drive transmission state at the time of normal rotation output of the drive transmission device of the embodiment 2, and shows a cross-sectional state as viewed from the radial direction of the rotation shaft. FIG. 5 is an explanatory view showing a drive transmission state at the time of reverse output of the drive transmission device of the second embodiment, and shows a cross-sectional state as viewed from the radial direction of the rotation shaft.

Hereinafter, embodiments of the present invention will be described based on the drawings.
FIG. 1 is a view showing a schematic configuration of an image forming apparatus 100 provided with a drive transmission device A of Embodiment 1 of the present invention.
As shown in the figure, the image forming apparatus 100 includes an automatic document feeder 110, a reader 120, an image forming device 130, a fixing device 140, a sheet feeding device 150, a sheet discharging device 160, and a sheet refeeding device 170. There is.

  The automatic document feeder 110 has a document feeding mechanism corresponding to sheet-through reading in this embodiment. The reading device 120 is a known device that reads an original document fed to a reading position by the automatic document feeder 110 while the document is being conveyed.

  The image forming device 130 is a known device including a photosensitive member, a charger, an optical writing unit, a developing unit, a transfer unit, a cleaning unit, a discharging unit, and the like. That is, the image forming apparatus 130 forms a latent image by the light writing unit on the photosensitive member to which a potential is applied by the charger, and the toner image obtained by developing the latent image by the developing unit is transferred onto the recording paper by the transfer unit. Transfer to Further, the toner remaining without being transferred is cleaned by the cleaning unit, and the potential remaining on the surface of the photosensitive member is returned to the zero potential by the discharging unit.

The fixing device 140 includes a fixing roller in which a pressure roller and a heat roller are paired.
The sheet feeding device 150 draws out the recording sheets stacked in the sheet feeding cassette one by one and feeds the recording sheets to the transfer unit side of the imaging device 130.
The sheet discharge device 160 can discharge the recording sheet conveyed from the fixing device 140 to the sheet discharge tray 163 and switch back to the sheet refeed device 170 side.
That is, when the sheet discharge device 160 includes a pair of sheet discharge rollers 161 and 161 and detects a nip state in which the recording paper is pinched by the sheet discharge rollers 161 and 161 by a sheet discharge sensor (not shown), The paper discharge rollers 161 and 161 are reversely rotated and supplied to the paper re-feed device 170.

  The sheet re-feed device 170 is a recording sheet nipped by the sheet discharge rollers 161 and 161 of the sheet discharge device 160 after being imaged by the image forming device 130 and passes through a switchback path 171 indicated by a dotted line on the back surface thereof. The image forming apparatus 130 is supplied as a transferable direction. Note that the pair of sheet discharge rollers 161, 161 has a structure in which both rotate in reverse with respect to the rotational input by meshing the external gear.

In the image forming apparatus 100 described above, the drive transmission device A of the first embodiment is used for forward and reverse rotation of the paper discharge roller 161 of the paper discharge device 160 described above.
The drive transmission device A will be described below with reference to FIGS. 2 and 3.
As shown in FIGS. 2 and 3, the drive transmission device A includes an input-side rotation shaft 1 rotationally input from a motor (not shown) and an output-side rotation shaft 2 rotationally outputting to the discharge roller 161. There is.

  The input-side rotation shaft 1 coaxially includes a first input-side rotating body 11 and a second input-side rotating body 12, and the rotation center shaft 31 of the drive gear 3 rotationally input from a motor (not shown) as a drive source. Are arranged parallel to the axial direction.

The first input-side rotating body 11 is an external gear coupled to the input-side rotating shaft 1 so as to be integrally rotatable, and a gear 11 a meshing with the drive gear 3 is formed on the outer periphery.
The second input-side rotating body 12 is a pulley that performs drive transmission to the belt 4 by friction, and is provided with the input-side clutch 5 interposed with respect to the input-side rotating shaft 1. Therefore, the second input rotary body 12 rotates integrally with the input rotary shaft 1 in the engaged state of the input clutch 5 and idles with respect to the input rotary shaft 1 in the released state of the input clutch 5.
That is, the input side clutch 5 is provided on the input side rotation shaft 1 as an input side drive switching unit that switches the drive transmission state and the transmission cutoff state between the first input side rotary body 11 and the second input side rotary body 12. ing.

  The output side rotation shaft 2 is disposed in parallel with the input side rotation shaft 1 at the position of the input side rotation shaft 1 in the outer diameter direction. Further, the rotation of the output side rotary shaft 2 is transmitted to the paper discharge roller 161.

Furthermore, a first output rotary body 21 and a second output rotary body 22 are provided coaxially with the output rotary shaft 2.
The first output side rotary body 21 is constituted by an external gear including on its outer periphery a gear 21a meshing with the gear 11a of the first input side rotary body 11, and provided on the output side rotary shaft 2 via the output side clutch 6 ing. Therefore, the first output side rotating body 21 rotates integrally with the output side rotating shaft 2 in the engaged state of the output side clutch 6 and idles with respect to the output side rotating shaft 2 in the released state of the output side clutch 6.
That is, the output-side clutch 6 is provided on the output-side rotating shaft 2 as an output-side drive switching unit that switches the drive transmission state and the transmission cutoff state between the first output side rotating body 21 and the second output side rotating body 22. ing.

  The second output side rotary body 22 is a pulley that performs drive transmission to the belt 4 by friction, and is disposed at the same height in the axial direction so as to be able to transmit rotation via the second input side rotary body 12 and the belt 4 It is provided integrally with the side rotation shaft 2. A gear may be formed on the inner periphery of the belt 4 and the outer periphery of both the rotating bodies 12 and 22 to form a meshing structure.

(Operation of Embodiment 1)
(At normal output)
At the time of forward rotation output to rotate the output side rotation shaft 2 in the same direction as the drive gear 3 to which the rotation of the motor (not shown) is transmitted, the input side clutch 5 is released (OFF) and the output side clutch 6 is engaged ( Turn on.

  2 (a) and 2 (b) show the transmission of the driving force at the time of the normal rotation output, and the rotation of the drive gear 3 in the direction of the arrow s11 is transmitted to the first input side rotary body 11, The input side rotation shaft 1 is transmitted in reverse in the direction of the arrow s12. At this time, since the input clutch 5 is released, the second input rotor 12 slips with respect to the input rotary shaft 1.

  On the other hand, on the output side rotating shaft 2, the rotation of the first input side rotating body 11 is transmitted to the first output side rotating body 21, and the first output side rotating body 21 rotates in the direction of arrow s14, that is, rotates forward. . Furthermore, the rotation of the first output side rotary body 21 is transmitted to the output side rotary shaft 2 through the output side clutch 6, and the output side rotary shaft 2 also performs normal rotation in the direction of the arrow s14.

  Accordingly, the paper discharge roller 161 (see FIG. 1) connected to the output side rotation shaft 2 also rotates forward. At this time, the second output side rotary body 22 integrally rotates with the output side rotary shaft 2, and the rotation is also transmitted to the second input side rotary body 12 through the belt 4. At this time, since the second input side rotating body 12 is separated from the input side rotating shaft 1 by the input side clutch 5 as described above, the second input side rotating body 12 idles with respect to the input side rotating shaft 1 rotating in the direction of the arrow s12. And rotate in the direction of the arrow s12b.

(During reverse output)
At the time of reverse output where the output side rotation shaft 2 is rotated in the opposite direction to the drive gear 3 to which the rotation of the motor (not shown) is transmitted, the input side clutch 5 is engaged (ON) and the output side clutch 6 is released (OFF ).
3 (a) and 3 (b) show the transmission of the driving force at the time of the reverse rotation output, and the rotation of the drive gear 3 in the direction of the arrow s11 is the same as that at the time of the normal rotation output. Transmitted to the body 11, the input side rotation shaft 1 is transmitted in the reverse direction in the direction of the arrow s12.
Then, at the time of this reverse rotation output, since the input side clutch 5 is engaged, the second input side rotating body 12 rotates integrally with the input side rotating shaft 1 in the direction of the arrow s12.

Further, the rotation of the second input side rotating body 12 is transmitted to the second output side rotating body 22 through the belt 4, and the second output side rotating body 22 and the output side rotating shaft 2 are in the direction of the arrow s13. That is, it rotates in the opposite direction to the rotation direction (s11) of the drive gear 3. Then, the discharge roller 161 connected to the output side rotation shaft 2 is also reversely rotated.
In the output side rotation shaft 2, the rotation of the first input side rotating body 11 is transmitted to the first output side rotating body 21, and the first output side rotating body 21 rotates in the direction of the arrow s14, that is, rotates forward. . However, at this time, since the output side clutch 6 is released, the first output side rotating body 21 idles with respect to the output side rotating shaft 2.

(Effect of Embodiment 1)
The effects of the first embodiment are listed below.
a) The drive transmission device of the first embodiment
An input-side rotation shaft 1 on which the first input-side rotating body 11 and the second input-side rotating body 12 are coaxially held;
The first output side rotating body 21 and the second input side rotating body 12 disposed at the outer diameter direction position of the first input side rotating body 11 and drivingly transmitted from the first input side rotating body 11 in the opposite rotating direction An output-side rotation shaft 2 on which the second output-side rotation body 22 disposed at the outer diameter direction position and driven and transmitted in the same direction as the rotation direction from the second input-side rotation body 12 is coaxially held;
The input side rotary shaft 1 and the first rotary shaft 1 are provided on the input side rotary shaft 1 to switch between the drive transmission state and the transmission cutoff state between the first input rotary body 11 and the second input rotary body 12. An input-side clutch 5 provided between the two-input-side rotating body 12;
An output side rotation shaft 2 and a second output side drive switching unit are provided on the output side rotation shaft 2 to switch the drive transmission state and the transmission cutoff state between the first output side rotation body 21 and the second output side rotation body 22. An output-side clutch 6 provided between the one-output-side rotating body 21;
It is characterized by having.
Thus, the input side rotation shaft 1 coaxially provided with both input side rotation bodies 11 and 12 and the output side rotation shaft 2 coaxially provided with both output side rotation bodies 21 and 22 are provided in parallel in the radial direction. Further, between the first and second members, there is not provided a configuration provided with a rotating shaft such as a gear for performing drive transmission.
Therefore, it is possible to reduce the space occupied in the radial direction, as compared with the case where the drive transmission member having the rotational shaft is interposed in the radial direction in addition to both the rotational shafts 1 and 2. This makes it possible to improve the degree of freedom of installation in the image forming apparatus 100.

b) The drive transmission device of the first embodiment
A paper discharge roller 161 is provided as a driven rotary member to be driven and transmitted from the output side rotary shaft 2,
The output-side clutch 6 as an output-side drive switching unit is characterized in that the drive transmission state and the transmission cutoff state are switched between the first output-side rotary body 21 and the output-side rotary shaft 2.
Therefore, the output side rotational shaft 2 can be rotated in the opposite direction to the input side rotational shaft 1 with the input side clutch 5 in the transmission / disconnection state (release) and the output side clutch 6 in the drive transmission state (engagement). On the other hand, the input side clutch 5 can be in a drive transmission state (engagement), the output side clutch 6 can be in a transmission interruption state (release), and the output side rotation shaft 2 can be rotated in the same direction as the input side rotation shaft 1.
As described above, it is possible to transmit the driving force (rotation) to the sheet discharge roller 161 as a non-drive rotating body by rotating the output side rotation shaft 2 forward and reverse.

c) The drive transmission device of the first embodiment
A drive transmission means of the first input side rotating body 11 and the first output side rotating body 21 is a means in which gears 11a and 21a as external gears formed on the outer periphery of both the rotating bodies 11 and 21 mutually mesh And
It is characterized in that the drive transmission means of the second input side rotary body 12 and the second output side rotary body 22 is the belt 4 wound around both.
Therefore, in the drive transmission via the first input rotary body 11 and the first output rotary body 21, the rotation is transmitted from the input rotary shaft 1 to the output rotary shaft 2 as a reverse rotation. On the other hand, in drive transmission via the second input rotary body 12 and the second output rotary body 22, rotation is transmitted from the input rotary shaft 1 to the output rotary shaft 2 as rotation in the same direction.
Thus, the case where the first input side rotating body 11 and the first output side rotating body 21 are used as the drive transmission system, and the case where the second input side rotating body 12 and the second output side rotating body 22 are used. The direction of rotation between the two rotation axes 1 and 2 can be changed in the opposite direction.
Further, in the case of drive transmission via the belt 4, quietness in a high speed rotation range can be expected compared to drive transmission via a plurality of gears.

d) The output side rotary shaft 2 of the drive transmission device A according to the first embodiment is characterized in that the drive transmission can be performed to the paper discharge roller 161 of the image forming apparatus 100.
Therefore, when switching the rotation direction of the discharge roller 161 to forward rotation and reverse rotation, it is possible to switch the rotation direction without changing the rotation direction of the motor, and reduce the occupied space in the radial direction of the drive transmission device A. be able to.

Second Embodiment
Next, a drive transmission device B according to the second embodiment will be described based on FIGS. 4 and 5.
Since drive transmission device B is a modification of the first embodiment, the same reference numerals as in the first embodiment are given to the same components as the first embodiment, and the description thereof is omitted.

  As shown in FIGS. 4 and 5, the second input-side rotating body 212 provided coaxially with the input-side rotating shaft 201 is constituted by an internal gear having a gear 212a formed inside the outer peripheral edge portion. . The second input side rotary body 212 is driven by the input side clutch 205 so as to rotate integrally with the input side rotary shaft 201 (fastening), and is disconnected when the input side rotary shaft 201 is idle (free). Can be switched to

  On the other hand, the second output side rotary body 222 provided coaxially with the output side rotary shaft 202 is constituted by an external gear having a gear 222a formed on the outer periphery, and the gear 222a is a gear of the second input side rotary body 212. It is engaged with 212a.

(Operation of Embodiment 2)
(At normal output)
At the time of normal rotation output to rotate the output side rotation shaft 202 in the same direction as the drive gear 3 to which the rotation of the motor (not shown) is transmitted, the input side clutch 205 is released (OFF) and the output side clutch 6 is engaged ( Turn on.

  FIG. 4 shows a state of transmission of the driving force at the time of the normal rotation output, and the rotation of the drive gear 3 in the direction of the arrow s21 is transmitted to the first input side rotating body 11, and the input side rotating shaft 201 , And transmitted in the direction of arrow s22. At this time, since the input clutch 205 is released, the second input rotary member 212 idles with respect to the input rotary shaft 201.

  On the other hand, on the output side rotating shaft 202, the rotation of the first input side rotating body 11 is transmitted to the first output side rotating body 21, and the first output side rotating body 21 rotates in the direction of arrow s23, that is, rotates forward. . Furthermore, the rotation of the first output side rotary body 21 is transmitted to the output side rotary shaft 202 via the output side clutch 6, and the output side rotary shaft 202 also performs normal rotation.

  Therefore, the paper discharge roller 161 (see FIG. 1) connected to the output side rotation shaft 202 also rotates forward. At this time, the second output rotary body 222 rotates integrally with the output rotary shaft 202, and the rotation is also transmitted to the second input rotary body 212 via the gears 222a and 212a. At this time, since the second input rotary member 212 is separated from the input rotary shaft 201 by the input clutch 205 as described above, the second rotary member 212 idles relative to the input rotary shaft 201 and rotates in the direction of the arrow s24. Do.

(During reverse output)
At the time of reverse output where the output side rotation shaft 202 is rotated in the opposite direction to the drive gear 3 to which the rotation of the motor (not shown) is transmitted, the input side clutch 205 is engaged (ON) and the output side clutch 6 is released (OFF ).
FIG. 5 shows the transmission of the driving force at the time of the reverse output, and the rotation of the drive gear 3 in the direction of the arrow s21 is transmitted to the first input-side rotating body 11 as in the normal rotation. The input side rotation shaft 201 is reversely transmitted in the direction of the arrow s22.
Then, at the time of this reverse rotation output, since the input side clutch 205 is engaged, the second input side rotating body 212 rotates integrally with the input side rotating shaft 201 in the direction of the arrow s22.

Furthermore, the rotation of the second input rotary member 212 is transmitted to the second output rotary member 222 via the gears 212a and 222a, and the second output rotary member 222 and the output rotary shaft 202 are indicated by the arrow s25. , Ie, in the direction opposite to the rotational direction (s21) of the drive gear 3. Then, the discharge roller 161 connected to the output side rotation shaft 202 is also reversely rotated.
In the output side rotation shaft 202, the rotation of the first input side rotating body 11 is transmitted to the first output side rotating body 21, and the first output side rotating body 21 rotates in the direction of the arrow s23, that is, rotates forward. . However, at this time, since the output side clutch 6 is released, the first output side rotating body 21 slips with respect to the output side rotating shaft 202.

Therefore, even in the second embodiment, the effects of the above a) and b) are exhibited.
In addition, in the drive transmission device B according to the second embodiment, the internal gear in which the drive transmission means of the second input rotary member 212 and the second output rotary member 222 is formed on the second input rotary member 212. And gear 222a as an external gear formed on the outer periphery of the second output side rotating body 222.
Therefore, the rotation of the input side rotation shaft 201 can be transmitted as rotation in the same direction to the output side rotation shaft 202 via the second input side rotation body 212 and the second output side rotation body 222.
Moreover, since the second input side rotary body 212 is an internal gear, it is possible to expect low noise and low vibration drive as compared with the case of meshing external gears.

As a modification of the second embodiment, as shown in FIG. 5, the output gear 300 is engaged with the second output side rotating body 222, and the output gear 300 is used as a driven rotating body, the paper discharge roller 161, etc. And may be provided coaxially.
As described above, by providing variations in the output form from the output side rotation shaft 2, it is possible to improve the degree of freedom in design.

  As mentioned above, although embodiment of this invention was described, this invention is not limited to such embodiment, A various deformation | transformation and substitution can be added in the range which does not deviate from the summary of this invention.

For example, in the embodiment, the drive transmission apparatus of the present invention is used for the drive transmission between the motor and the paper discharge roller in the image forming apparatus, but the present invention is not limited to this.
Specifically, it is used for rotation of an image carrier for visualizing a toner image in a developing unit of an image forming apparatus of an image forming apparatus, similarly for rotation of an intermediate transfer belt in a transfer unit of the image forming apparatus, It can be used to rotate the photosensitive member of the imaging device. Furthermore, it can also be used to rotate the roller of the fixing device of the image forming apparatus.

Moreover, although the input side drive switching part showed the example provided between the input side rotating shaft and the 2nd input side rotary body in embodiment, the 1st input side rotary body and the 2nd input side rotary body were shown. The installation position is not limited to this as long as the drive transmission state and the transmission cutoff state are switched between them.
For example, the input drive switching unit may be provided in the middle of the input rotary shaft, and transmission / shutoff may be performed between the first input rotary member and the second input rotary member on the input rotary shaft. Alternatively, the input drive switching unit may be provided between the first input rotary body and the input rotary shaft.
More specifically, in the former case, the input-side rotation shaft 1 in the first embodiment is used as the first axis on the first input-side rotating body 11 side in the axial direction and the second axis on the second input-side rotating body 12 side. The two axes are arranged in series in the axial direction. Then, between the first axis and the second axis, transmission / disconnection of the driving force can be performed by the input side drive switching unit such as the input side clutch 5 or the like.
In the latter case, the input side drive switching unit such as the input side clutch 5 is provided between the input side rotary shaft 1 and the first input side rotary body 11 when the structure described in the first embodiment is described. Transmission / shutoff of driving force can be performed between 1, 11.

In the embodiment, the output drive switching unit is provided between the output rotary shaft and the second output rotary body. However, the first output rotary body and the second output rotary body are illustrated. As long as the drive transmission state and the transmission cutoff state are switched between them.
For example, the output drive switching unit may be provided in the middle of the output rotary shaft, and transmission / shutoff may be performed between the first output rotary body and the second output rotary body on the output rotary shaft.
More specifically, the output side rotary shaft 2 shown in the first embodiment is divided into a first axis on the first output side rotary body 21 side and a second shaft on the second output side rotary body 22 in the axial direction. And are arranged in series in the axial direction. Then, between the first axis and the second axis, transmission / disconnection of the driving force can be performed by the input side drive switching unit such as the output side clutch 6 or the like.
Alternatively, the output drive switching unit may be provided between the second output rotary body and the output rotary shaft. In this case, the output side rotating shaft is always rotated in the same direction as the first output side rotating body, and the output from the output side rotating shaft is performed from the second output side rotating body.
More specifically, in the structure shown in the first embodiment, the input drive switching unit such as the output clutch 6 can be provided between the output rotary shaft 2 and the second output rotary body 22. . And in this case, since the rotation direction of the output side rotating shaft 2 is one direction, the output from the output side rotating shaft 2 is the second output side as described in the modification of the second embodiment. It is performed from the rotating body 22. As the rotational output, as described in the second embodiment, a belt, a chain, or the like can be used in addition to the engagement with the output gear 300.

  Furthermore, the rotation transmitting means of the first input side rotating body and the first output side rotating body and the rotation transmitting means of the second input side rotating body and the second output side rotating body are limited to those shown in the embodiment. I will not. For example, it is also possible to use a belt or the like for the drive transmission between the first input side rotating body and the first output side rotating body. In this case, in order to rotate in the reverse direction, the belt is crossed between the two rotating bodies and wound around each of the rotating bodies. In addition, an external gear can be used as the rotation transmitting means of the second input side rotating body and the second output side rotating body. In this case, in order to rotate both rotating bodies in the same direction, an external gear is interposed between the two.

1 input side rotary shaft 2 output side rotary shaft 4 belt 5 input side clutch (input side drive switching portion)
6 Output clutch (Output drive switching unit)
11 1st input side rotary body 12 2nd input side rotary body 21 1st output side rotary body 22 2nd output side rotary body 100 Image formation device 161 discharge roller (driven rotary body)
201 Input side rotary shaft 202 Output side rotary shaft 205 Input side clutch (input side drive switching unit)
212 Second input side rotary body 212a gear (internal gear)
222 Second Output Rotor 222a Gear (External Gear)
300 output gear (driven rotor)
A Drive transmission device B Drive transmission device

Unexamined-Japanese-Patent No. 2010-023983

Claims (11)

A first rotation axis,
A first rotating body and a third rotating body provided on the first rotation shaft,
A first drive switching unit that switches between drive transmission and drive cutoff between the first rotation shaft and the first rotation body, or between the first rotation shaft and the third rotation body;
A second rotation axis,
A second rotating body and a fourth rotating body provided on the second rotation shaft,
A second drive switching unit that switches between drive transmission and drive cutoff between the second rotation shaft and the second rotation body or between the second rotation shaft and the fourth rotation body;
A drive transmission rotator that transmits the driving force from a drive source to the first rotator;
Drive transmission device comprising
The first rotating body and the second rotating body are drivingly connected to rotate in opposite directions to each other, while the third rotating body and the fourth rotating body are driven to rotate in the same direction. Are linked and
In accordance with the switching operation of the first drive switching unit and the second drive switching unit at the time of operation of the drive source, the rotational directions of the third rotating body and the fourth rotating body are switched in forward and reverse directions. A drive transmission device characterized by In the drive transmission device according to claim 1,
The drive transmission device, wherein the first rotating body and the second rotating body are both external gears. In the drive transmission device according to claim 2,
A drive transmission device characterized in that the first rotating body and the second rotating body are drive-connected by the mutual engagement of their external teeth. The drive transmission device according to any one of claims 1 to 3.
A drive transmission device characterized in that the third rotating body and the fourth rotating body are connected to each other by winding a belt on each other. The drive transmission apparatus according to any one of claims 1 to 4.
The drive transmission apparatus according to claim 1, wherein the first drive switching unit switches drive transmission and drive interruption between the first rotation shaft and the third rotation body. In the drive transmission device according to claim 5,
The second drive switching unit switches between drive transmission and drive cutoff between the second rotation shaft and the second rotation body. The drive transmission apparatus according to any one of claims 1 to 6.
The drive transmission device is characterized in that the drive transmission rotary body is drivingly connected to the first rotary body. The drive transmission apparatus according to any one of claims 1 to 7.
A drive transmission apparatus characterized in that the third rotating body and the fourth rotating body are drivingly connected to a driven rotating body. In the drive transmission device according to claim 8 ,
The drive transmission device, wherein the driven rotary body is a paper discharge roller of an image forming apparatus. The drive transmission device according to any one of claims 1 to 9 .
The drive transmission device, wherein the first drive switching unit and the second drive switching unit are electromagnetic clutches.   An image forming apparatus comprising the drive transmission device according to any one of claims 1 to 10.