The present disclosure relates to an image forming apparatus such as a printer, a copier, a recording device, or a facsimile.
In recent years, a demand for slowing down a process speed in image formation with respect to a recording sheet has existed to suppress operation sound generated from an image forming apparatus. On the other hand, when the process speed is decreased, a throughput in related art is not achieved. However, when a sheet interval is shortened, since the process speed can be decreased while the throughput is maintained, deliberation has been made to shorten the sheet interval. The sheet interval refers to a distance from a trailing edge of a preceding sheet to a leading edge of a succeeding sheet when images are continuously formed on a plurality of recording sheets.
For example, a configuration has been proposed in which a conveyance malfunction is avoided by performing acceleration and deceleration of a conveyance speed of the recording sheet in a section from a top sensor arranged on an upstream side in a conveyance direction with respect to a transfer part to the transfer part (for example, see Japanese Patent Laid-Open No. 2014-035379). In addition, a configuration has been proposed in which a section where the acceleration and deceleration can be performed is lengthened by adding a sensor on the upstream side in the conveyance direction with respect to the top sensor (for example, see Japanese Patent Laid-Open No. 2014-041296).
However, according to the configuration in which the top sensor is arranged on the upstream side with respect to the transfer part, and the conveyance speed of the recording sheet is accelerated in accordance with a timing when the recording sheet is detected by the top sensor, the section where the conveyance speed of the recording sheet can be accelerated is limited to the section from the sensor to the transfer part. For this reason, in a case where the sheet interval is further shortened, a motor needs to be driven at a further faster speed. For this reason, increase in the operation sound or used torque of the motor becomes an issue. In addition, according to the configuration in which the sensor is arranged on the upstream side with respect to the top sensor, a sensor different from the top sensor is added, and increase in costs becomes an issue.
The information in the present disclosure works towards reducing operation sound or used torque of a motor without adding a new sensor.
According to an aspect of the present invention, an image forming apparatus includes an image bearing member, a transfer unit configured to form a nip portion together with the image bearing member and transfer a toner image formed on the image bearing member to a recording material in the nip portion, a feeding unit configured to feed a recording material stacked in an accommodation portion to a conveyance path, a conveyance unit that is arranged along the conveyance path and configured to convey the recording material fed by the feeding unit, a first driving unit configured to drive the feeding unit and the conveyance unit, a detection unit that is arranged between the conveyance unit and the transfer unit and configured to detect the recording material, and a control unit configured to control in a manner that image formation to the image bearing member is started based on a timing when a leading edge of the recording material is detected by the detection unit, wherein the control unit changes a conveyance speed of a first recording material from a first speed to a second speed, that is faster than the first speed, before a leading edge of the first recording material fed by the feeding unit is detected by the detection unit to perform conveyance by the conveyance unit, controls the first driving unit in a manner that the conveyance speed of the first recording material is changed from the second speed to the first speed before the leading edge of the first recording material reaches the nip portion based on a timing when the leading edge of the first recording material is detected by the detection unit, and obtains a timing for the image formation to the image bearing member based on a timing when the conveyance speed is changed from the second speed to the first speed.
Further features will become apparent from the following description of embodiments with reference to the attached drawings.
Hereinafter, embodiments will be described in detail with reference to the drawings.
Image Forming Apparatus
A feeding roller 102 functioning as a feeding unit supplies sheets P corresponding to recording media stacked on a sheet cassette 101 to a conveyance path one by one. The sheet cassette 101, a manual feed tray which is not illustrated in the drawing, or the like functions as an accommodation portion that accommodates the sheets P to be supplied to the conveyance path. Conveyance rollers 103 and registration rollers 104 further convey the sheet P to a downstream side of the conveyance direction. The conveyance rollers 103 and the registration rollers 104 are examples of conveyance units configured to convey the sheet P from the sheet cassette 101 to a transfer roller 106 functioning as a transfer unit. In addition, the registration rollers 104 is a conveyance unit arranged so as to be closest to the transfer roller 106 among the conveyance units. That is, the registration rollers 104 are rollers located on the most downstream side among the conveyance units on an upstream side in a conveyance direction of the sheet P with respect to the transfer roller 106. On the other hand, the conveyance rollers 103 are located on the most upstream side in the conveyance direction of the sheet P among the conveyance units.
A top sensor 105 functioning as a detection unit configured to detect the sheet P is arranged in a section on a conveyance path from the registration rollers 104 to the transfer roller 106 (hereinafter, which will be referred to as a conveyance section). The top sensor 105 is arranged on the upstream side in the conveyance direction of the sheet P with respect to the transfer roller 106 (hereinafter, which will be referred to as the upstream side). The conveyance rollers 103 and the registration rollers 104 are arranged on the upstream side with respect to the transfer roller 106. When the sheet P passes through a nip portion formed by the photosensitive drum 122 and the transfer roller 106 (hereinafter, which will be referred to as transfer nip portion), the toner image is transferred from the photosensitive drum 122 to the sheet P. A transfer unit such as the transfer roller 106 (transfer blade depending on the image forming apparatus) functions as a transfer unit configured to transfer the toner image formed by the photosensitive drum 122 to the sheet P.
A fixing apparatus 130 is provided with a thermistor 131, a heater 132, a fixing film 133, and a pressurizing roller 134. The fixing apparatus 130 maintains a certain temperature of the heater 132 based on a temperature detected by the thermistor 131. The toner image is fixed onto the sheet P by the fixing film 133 and the pressurizing roller 134. When the sheet P in which the fixing processing is ended is detected by a sheet discharge sensor 109, the sheet P is discharged to a tray 112 or a tray 113. It should be noted that the tray 112 is closed as illustrated in
Relationships Among the Respective Rollers and Motors
Block Diagram Illustrating a Control System of the Image Forming Apparatus
To form and fix an image onto the sheet P, the image formation control unit 201 controls a development voltage generation circuit 126, the heater 132, and an image signal output unit 400. The development voltage generation circuit 126 generates a development voltage applied to the development roller 121. The image signal output unit 400 outputs an image signal to the optical box 108 by using the sub scanning synchronization signal output from the image formation control unit 201 as a starting point. The sub scanning synchronization signal is generated by the conveyance control unit 202 and output to the image signal output unit 400 via the image formation control unit 201. The optical box 108 controls on and off of the laser in accordance with the image signal.
The conveyance control unit 202 monitors the detection signal of the top sensor 105 to determine an output timing of the sub scanning synchronization signal and control driving of the conveyance motor 301 and the fixing motor 302. The detection signal of the top sensor 105 indicates whether or not the sheet P has passed, that is, indicates a sheet present state or a sheet absent state. When the detection signal is changed from the “sheet absent state” to the “sheet present state”, the conveyance control unit 202 recognizes that a leading edge of the sheet P has arrived. On the other hand, when the detection signal is changed from the “sheet present state” to the “sheet absent state”, the conveyance control unit 202 recognizes that a trailing edge of the sheet P has passed.
In a case where the plurality of sheets P are continuously conveyed on the conveyance path, a predetermined sheet P is set as a preceding sheet, and the sheet P that is subsequently to be conveyed (or being conveyed) after the preceding sheet is set as a succeeding sheet. The sheets continuously conveyed are assigned with reference symbols such as P1, P2, P3, and the like. The preceding sheet P1 is a sheet that is fed immediately before among the fed sheets preceding the succeeding sheet P2. A sheet interval measurement unit 204 measures an actual sheet interval that is a conveyance interval from the trailing edge of the preceding sheet P1 corresponding to a second recording material to the leading edge of the succeeding sheet P2 corresponding to a first recording material by using the detection signal from the top sensor 105. A parameter storage unit 205 stores data such as parameters used for a calculation unit 206 to perform calculation and a conveyance speed used by a driving control unit 207. The parameters include, for example, the conveyance speed determined by performances of the conveyance motor 301, an ascending time Taa, a descending time Tda, and the like. The ascending time Taa is a time used for accelerating the conveyance speed from a first speed, for example, a first speed Vp1 at which the image is formed on the photosensitive drum 122, to a second speed Vp2, for example, a speed after the acceleration for improving productivity. The descending time Tda is a time used for decelerating the conveyance speed from Vp2 to Vp1.
The calculation unit 206 executes various calculations based on various numeric expressions which will be described below. The driving control unit 207 controls the conveyance motor 301 and the fixing motor 302 in accordance with the timing and the conveyance speed determined by the calculation unit 206. For example, the driving control unit 207 can change the number of rotations of the conveyance motor 301 by changing a cycle of a clock.
A synchronization signal output unit 208 outputs the sub scanning synchronization signal to the image formation control unit 201 at a timing when a predetermined time (time Ttop which will be described below) elapses from a timing when the top sensor 105 detects the leading edge of the sheet P. Since the output of the sub scanning synchronization signal and the light emission of the laser light are started, the image is formed on the photosensitive drum 122 in a manner that the image is transferred from 0 mm at the leading edge of the sheet P. That is, the timing when the time Ttop has elapsed from the timing when the top sensor 105 detects the leading edge of the sheet P is the timing for the start of the image formation. The conveyance control unit 202 starts the feeding of the succeeding sheet P2 at the timing when the top sensor 105 detects the trailing edge of the preceding sheet P1.
Distance Relationships Among the Members on the Conveyance Path
The time Ttop extending from the timing when the top sensor 105 detects the leading edge of the sheet P until the sub scanning synchronization signal is output will be described with reference to
Ttop1=(Lf−Ld)/Vd (1)
It should be noted that the top sensor 105 is arranged in a manner that the distance Lf is set to be longer than the distance Ld (Lf>Ld). It should be noted that a distance L1 is set as a distance from the feeding roller 102 to the top sensor 105, and a distance L3 is set as a sheet interval corresponding to a target set for the preceding sheet P1 and the succeeding sheet P2. Details of the distances L1 and L3 will be described below.
Conveyance Control of the Sheet
Conveyance control of the sheet P according to the present embodiment will be described in detail with reference to a flow chart illustrated in
The controller 200 starts step 500 and subsequent steps (hereinafter, which will be referred to as S) of
According to the present embodiment, after the trailing edge of the preceding sheet P1 passes through the top sensor 105, the preceding sheet P is conveyed by the photosensitive drum 122 and the transfer roller 106 which are driven by the fixing motor 302 (see
In S502, the controller 200 determines whether or not the top sensor 105 detects the leading edge of the succeeding sheet P2, that is, the detection signal of the top sensor 105 is changed from the sheet absent state to the sheet present state. In a case where the controller 200 determines in S502 that the top sensor 105 does not detect the leading edge of the succeeding sheet P2, the processing returns to S502. In a case where the controller 200 determines in S502 that the leading edge of the succeeding sheet P2 is detected, the processing proceeds to S503. In (a) of
In S503, the controller 200 calculates a time Tx extending from the timing 500t when the feeding of the succeeding sheet P2 is started until a timing (deceleration timing) 505t when the conveyance motor 301 is started by the calculation unit 206 of the conveyance control unit 202. Descriptions of the time Tx will be described below. In addition, the controller 200 calculates the time Ttop when the image formation on the photosensitive drum 122 of the succeeding sheet P2 is started by using the timing 500t for starting the feeding of the succeeding sheet P2 as a starting point by the calculation unit 206 based on the following expression (2).
Ttop=Tx+Tda−Ld/Vd (2)
In S504, the controller 200 refers to the timer which is not illustrated in the drawing and determines whether or not the time has reached the deceleration timing of the conveyance motor 301, that is, the time Tx has elapsed. In a case where the controller 200 determines in S504 that the time has not reached the deceleration timing of the conveyance motor 301, the processing returns to S504. In a case where the controller 200 determines in S504 that the time has reached the deceleration timing, the processing proceeds to S505. In S505, the controller 200 returns the speed of the conveyance motor 301 to the first speed Vp1 by the driving control unit 207 of the conveyance control unit 202. The processing in S505 is equivalent to the timing 505t of
Deceleration Timing (the Time Tx)
With reference to
The time T1 is a time extending from the timing t11 when the feeding of the succeeding sheet P2 is started until the timing t14 when the leading edge of the succeeding sheet P2 reaches the transfer nip portion. Since the conveyance speed is accelerated from the first speed Vp1 to the second speed Vp2 during a period between the timing t11 and the timing t14, the succeeding sheet P2 can proceed farther by a distance Ln than the preceding sheet P1. In
At this time, as illustrated in
Therefore, the time T2 becomes a solution with which the area of the shaded part illustrated in
Where v1(t) indicates the conveyance speed of the succeeding sheet P2 in an interval between the timing t11 and a timing t12. In addition, v2(t) indicates the conveyance speed of the succeeding sheet P2 in an interval between the timing t12 and the timing t13. Furthermore, v3(t) indicates the conveyance speed of the succeeding sheet P2 in an interval between the timing t13 and the timing t14.
Since v1(t) and v3(t) depend on characteristics of the conveyance motor 301, v1(t) and v3(t) may be represented by not only linear functions but also high-dimensional functions such as quadratic functions in some cases. In addition, v1(t) and v3(t) may be discrete functions. For example, v1(t) and v3(t) may take variable and discrete values between 1.0 time and 1.5 times as fast as the first speed Vp1. It should be noted that the second speed Vp2 may be a fastest speed corresponding to a performance limit of the conveyance motor 301 or may be another speed. When the second speed Vp2 is set as fastest speed corresponding to the performance limit of the conveyance motor 301, the sheet interval can be set to be close to the distance L3 in a short period of time. It should be noted however that driving sound of the conveyance motor 301 becomes the loudest. In view of the above, to reduce the driving sound, the section from the feeding position of the sheet P to the position of the transfer nip portion (the section L1+Lf in terms of distance and the period T1 in terms of time) may be optimized such that the sheet interval is set to be close to the distance L3. That is, when the second speed Vp2 corresponding to a slowest limit at which the distance Ln can be shortened is selected during the time T1, the driving sound can be minimized. That is, the second speed Vp2 may be set within an allowable range of the driving sound. In this manner, the driving sound and the speed of the conveyance motor 301 have a trade-off relationship.
Herein, for convenience of the explanation, it is assumed that both an acceleration when the speed is accelerated from the first speed Vp1 to the second speed Vp2 and an acceleration when the speed is decelerated from the second speed Vp2 to the first speed Vp1 are constant. The area of the shaded part of
Ln=(T1+T2)×(Vp2−Vp1)/2 (4)
When the time T2 is obtained by transforming the expression, the following expression (5) is obtained.
T2=2Ln/(Vp2−Vp1)−T1 (5)
Since the preceding sheet P1 is moved by the distance (Lf+L3) at the first speed Vp1 during the time T1, the following expression is obtained.
T1=(Lf+L3)/Vp1 (6)
At this time, when the expression (6) is assigned to the expression (5), the following expression (7) is obtained.
T2=2Ln/(Vp2−Vp1)−(Lf+L3)/Vp1 (7)
It should be noted that the first speed Vp1, the second speed Vp2, and the distance Lf are already found, and those pieces of information are stored in the parameter storage unit 205.
In addition, as described above, the following expression (8) is established from
Ln=L1−L3 (8)
Therefore, the distance Ln is determined from the expression (8) based on the configuration of the image forming apparatus 100. That is, it is possible to calculate the time T2 from the expression (7). It should be noted that the expression (7) can be represented as follows by using three coefficients α, β, and γ which can be obtained in advance.
T2=α+β×L3+γ×L3 (7′)
It should be noted that α is determined from L1, Vp1, Vp2, and Lf, β is determined from Vp1 and Vp2, and γ is determined from Vp1. Since the transformation process from the expression (7) to the expression (7′) is redundant, the descriptions thereof will be omitted.
The time T2 is equivalent to the time until the time Tx elapses in S504 of
The ascending time Taa and the descending time Tda are the times determined by the second speed Vp2, the characteristics of the conveyance motor 301 (such as characteristics of the load torque and the motor driver), and the like. Therefore, when the second speed Vp2 is determined, the ascending time Taa and the descending time Ida are also determined. It should be noted that, while a function and a table for determining the ascending time Taa and the descending time Ida from the second speed Vp2 are previously stored in the parameter storage unit 205, the calculation unit 206 reads these pieces of information to be used for the calculations.
As described above, according to the present embodiment, the section where the succeeding sheet P2 can be accelerated can be set from the start of the feeding of the succeeding sheet P2 to the transfer nip portion without adding the sensor. For this reason, in a case where the section where the acceleration can be performed without increasing the costs is extended, and the sheet interval is shortened by lengthening the section where the acceleration can be performed, it is possible to suppress the speed after the acceleration (the second speed Vp2). For this reason, without decreasing the throughput, it is possible to perform the conveyance control in which the increase in the driving sound or the lead torque of the motor is suppressed. In the above-described manner, according to the present embodiment, it is possible to reduce the operation sound or the used torque of the motor without adding the new sensor.
According to the first embodiment, the control in which the conveyance motor 301 is accelerated to shorten the sheet interval from the feeding of the succeeding sheet P2 is performed. According to the second embodiment, an example will be described in which one driving unit is used while the costs are further decreased as compared with the first embodiment. It should be noted that configurations similar to those of the first embodiment are assigned with the same reference symbols, and descriptions thereof will be omitted.
Relationships Among the Respective Rollers and Motors
Conveyance Control of the Sheet
The present embodiment will be described in detail with reference to the flow chart illustrated in
Similarly as in the first embodiment, the timing 700t of
A reason why standby occurs until the trailing edge of the preceding sheet P1 passes through the transfer nip portion is that the single conveyance motor 301 performs the entire driving of the image forming apparatus according to the present embodiment as described above. According to the present embodiment, if the speed of the conveyance motor 301 is changed from the first speed Vp1 to the second speed Vp2 in a period during which the preceding sheet P1 passes through the transfer nip portion, a rotation speed of the photosensitive drum 122 is changed. The period during which the preceding sheet P1 passes through the transfer nip portion is a period during which the toner image on the photosensitive drum 122 is transferred to the preceding sheet P1. In this manner, there is a possibility that a difference in the speed at which the laser light performs the image formation on the photosensitive drum 122 and the speed of the rotation of the photosensitive drum 122 itself occurs and an image is disturbed. To avoid the disturbance of the image, standby occurs until the preceding sheet P1 passes through the transfer nip portion.
In a case where the controller 200 determines in S701 that the trailing edge of the preceding sheet P1 has not passed through the transfer nip portion, the processing returns to S701. In a case where the controller 200 determines in S701 that the trailing edge of the preceding sheet P1 has passed through the transfer nip portion, the processing proceeds to S702. In S702, the controller 200 changes the speed of the conveyance motor 301 from the first speed Vp1 to the second speed Vp2 by the driving control unit 207 of the conveyance control unit 202. The determination method for the second speed Vp2 may be the same as that of the first embodiment with the following exceptions.
Differences in the determination method for the second speed Vp2 from that of the first embodiment resides in that the following two aspects. First, the acceleration of the conveyance speed of the succeeding sheet P2 is not performed until the trailing edge of the preceding sheet P1 passes through the transfer nip portion. Second, the deceleration to the first speed Vp1 needs to be completed by the image formation timing on the photosensitive drum 122. For this reason, as illustrated in
In addition, according to the present embodiment, the second speed Vp2 is changed in accordance with a sheet type. For example, in a case where the sheet type of the sheet P is thick paper (for example, a basis weight >120 g/m2), conveyance force of the conveyance motor 301 has no margin, the second speed Vp2 is set to be further decreased as compared with the case of the plain paper or thin paper. That is, the second speed Vp2 is determined as a slower speed as the basis weight of the sheet P is higher. It should be noted that, in a case where the sheet type of the sheet P is not identified, a configuration may also be adopted in which the second speed Vp2 is uniformly set as a fast speed or uniformly set as a slow speed to ensure the conveyance in accordance with the conveyance force of the feeding roller 102. Since the processing in S703 is the same as the processing in S502 of
In S704, the controller 200 calculates a timing when the speed of the conveyance motor 301 is switched from the second speed Vp2 to the first speed Vp1 by the driving control unit 207 of the conveyance control unit 202 (the time Tx) from the above-described expression (7′) by the calculation unit 206. This timing is equivalent to the timing 704t of
Ttop2=Tx+Tda (9)
The processing in S705 and S706 is similar to the processing in S504 and S505 of
Even in a case where the single driving unit is used as in the present embodiment, the switching from the first speed Vp1 to the second speed Vp2 is performed to change the second speed Vp2 in accordance with the sheet type of the sheet P. For this reason, the high productivity can be achieved even in a case where the driving unit is omitted for further decrease in the costs, and it is possible to execute the appropriate sheet conveyance even when the sheet type is changed. As described above, according to the present embodiment, it is possible to reduce the operation sound or the used torque of the motor without adding the new sensor.
Color Image Forming Apparatus
According to the third embodiment, a case will be described where the configuration is applied to a color image forming apparatus.
The sheets P are stacked in the sheet cassette, and the sheet P is fed by the feeding roller 102 driven at a predetermined timing by a conveyance motor 901 functioning as a second driving unit which will be described below and a driving transmission unit which is not illustrated in the drawing. The sheet P fed by the feeding roller 102 is conveyed by a transfer conveyance belt 152 functioning as a belt conveyance unit via the conveyance rollers 103 and the registration rollers 104. The transfer conveyance belt 152 is supported by a driving roller 150 functioning as a rotating unit and a driven roller 151. The transfer conveyance belt 152 is a belt-like member that is nipped between the plurality of photosensitive drums 122 and the plurality of transfer roller 106 and conveys the sheet P. The transfer conveyance belt 152 is driven so as to rotate in an anticlockwise direction in the drawing when the driving roller 150 rotates while being contacted with the photosensitive drum 122 by a development roller 902 (see
The transfer rollers 106 functioning as transfer units with respect to the sheet P are respectively applied with predetermined transfer voltages, and the toner images of the respective colors on the photosensitive drum 122 are transferred to the sheet P conveyed by the transfer conveyance belt 152, so that the toner images of the four colors are formed. The toner remaining on the photosensitive drum 122 is removed by a cleaner 153. The sheet P on which the toner images of the four colors are transferred is conveyed to the fixing apparatus 130, and the toner images are fused and fixed by heat and pressure onto the sheet P, so that the color image is obtained. The configuration of the fixing apparatus 130 is similar to the configuration described with reference to
Relationships Among the Respective Rollers and Motors
Distance Relationships Among the Members on the Conveyance Path
Conveyance Control of the Sheet
In S1101, the controller 200 starts the feeding of the succeeding sheet P2 by the driving control unit 207 of the conveyance control unit 202 and resets the timer which is not illustrated in the drawing to start. In S1102, the controller 200 determines whether or not the time has reached the change timing calculated in S1100 by referring to the timer. In a case where the controller 200 determines in S1102 that the time has not reached the change timing, the processing returns to S1102. In a case where the controller 200 determines in S1102 that the time has reached the change timing, the processing proceeds to S1103. For example, in a case where it is determined that the succeeding sheet P2 is the thin paper, the time has reached the change timing along with the feeding. On the other hand, in a case where the succeeding sheet P2 is the thick paper, it is determined that the time has reached the change timing when the leading edge of the succeeding sheet P2 has reached the conveyance rollers 103. Whether or not the leading edge of the succeeding sheet P2 has reached the conveyance rollers 103 is determined based on a distance between the feeding roller 102 and the conveyance rollers 103 along the conveyance path and the conveyance speed of the succeeding sheet P2 (Vp1). In S1103, the controller 200 changes the speed of the conveyance motor 901 from the first speed Vp1 to the second speed Vp2. Since the processing in S1104 is the same as the processing in S502 of
In S1105, the controller 200 calculates the deceleration timing (the time Tx) of the conveyance motor 901 by the calculation unit 206 of the conveyance control unit 202. In the calculation of the deceleration timing executed when the leading edge of the succeeding sheet P2 is detected by the top sensor 105, the deceleration timing (the time Tx) of the conveyance motor 901 can be calculated by using the above-described expression (7′). Herein, according to the present embodiment, the distance Lf in the expression (7′) varies in accordance with a relationship between the distance Lfa illustrated in
In addition, when the leading edge of the succeeding sheet P2 is detected by the top sensor 105, a time Ttop3 when the image formation on the photosensitive drum 122 is started is calculated from the following expression (10). It should be noted that, at this time, Ttop3 is calculated by using a timing when the acceleration of the conveyance speed of the succeeding sheet P2 from the first speed Vp1 to the second speed Vp2 is started as a starting point.
In the case of (Lfa≥Ld),
Ttop3=Tx+Ida+(Lfa−Ld)/Vd, and
in the case of (Lfa<Ld),
Ttop3=Tx+Ida (10)
The processing in S1106 and S1107 is similar to the processing in S504 and S505 of
In the above-described manner, according to the present embodiment, in the case of the color image forming apparatus, the speed of the conveyance motor 901 is switched from the first speed Vp1 to the second speed Vp2, and the timing for changing the speed to the second speed Vp2 can be varied in accordance with the sheet type of the succeeding sheet P2. For this reason, the high productivity also can be achieved in the color image forming apparatus, and the appropriate sheet conveyance can be executed even when the sheet type of the sheet P is changed. As described above, according to the present embodiment, it is possible to reduce the operation sound or the used torque of the motor without adding the new sensor.
While the present invention has been described with reference to embodiments, it is to be understood that the invention is not limited to the disclosed embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2016-095269 filed May 11, 2016, which is hereby incorporated by reference herein in its entirety.
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