JP2019142682A - Sheet feeding device and image formation device - Google Patents

Abstract

A sheet feeding apparatus and an image forming apparatus capable of accurately detecting a sheet having a basis weight larger than a predetermined value are provided. A sheet feeding device includes a detection unit that detects a behavior of a detection member that is in contact with a sheet conveyed along a conveyance path, and a trailing end of a sheet that is fed by the sheet feeding unit is a detection member. Based on the fact that the detection unit detects that the behavior of the detection member has changed due to contact, the sheet fed by the sheet feeding unit is determined to be a sheet having a basis weight larger than a predetermined value. And a control unit. [Selection] Figure 6

Description

  The present invention relates to a sheet feeding apparatus and an image forming apparatus that feed sheets.

  In general, in a printer or copying machine that forms an electrostatic image and fixes it with heat, the conveyance speed and the fixing temperature are made variable depending on the basis weight of the sheet. In particular, for thick paper such as envelopes and label paper, in order to avoid slippage due to sheet stiffness and to secure the fixing property to the sheet, the transport speed is set slower and the fixing temperature is set higher than that of plain paper.

  Conventionally, as means for detecting such thick paper, a method of detecting the paper thickness by the current of the transport motor (see Patent Document 1) or a method of detecting the thick paper by the time when the paper reaches the transport sensor (Patent Document 2 and 3) has been proposed.

JP 2003-285484 A JP-A-6-67481 JP 2009-280312 A

  However, the configuration of Patent Document 1 requires a dedicated sensor for detecting the thickness of the sheet, which increases the cost due to the addition of parts. In addition, a space for providing a dedicated sensor is also required, which increases the size of the apparatus.

  On the other hand, in the configurations of Patent Documents 2 and 3, a change in transportability due to the surface property of the sheet or roller wear is included in the time for the sheet to reach the transport sensor. There is a problem that the influence of the change in the transportability is large.

  SUMMARY An advantage of some aspects of the invention is that it provides a sheet feeding apparatus and an image forming apparatus that can accurately detect a sheet having a basis weight larger than a predetermined value.

  A sheet feeding apparatus according to the present invention includes a sheet storage unit that stores sheets, a sheet feeding unit that feeds sheets stored in the sheet storage unit, and a sheet fed by the sheet feeding unit. A curved conveyance path that guides, a detection unit that detects a behavior of a detection member that contacts a sheet conveyed along the conveyance path, and a trailing end of the sheet that is fed by the sheet feeding unit is the detection member The sheet fed by the sheet feeding unit is a sheet having a basis weight larger than a predetermined value based on the detection unit detecting that the behavior of the detection member has changed due to contact with the sheet. And a control unit that judges that

  The image forming apparatus according to the present invention includes a sheet storage unit that stores sheets, a sheet feeding unit that feeds sheets stored in the sheet storage unit, and a sheet fed by the sheet feeding unit. An image is formed on the sheet fed by the sheet feeding unit, a curved feeding path that guides the sheet, a detection unit that detects the behavior of the detection member that contacts the sheet conveyed along the conveyance path, and the sheet feeding unit. In the case where it is set that the image forming unit that performs the notification, the notification unit that notifies that the type of the sheet is different, and the sheet storage unit that stores a type of sheet having a basis weight smaller than a predetermined value, Based on the fact that the detection unit has detected that the behavior of the detection member has changed due to the trailing edge of the sheet fed by the sheet feeding unit being in contact with the detection member, the notification unit is controlled. A control unit for notifying that the type of the sheet is different, with a, characterized in that.

  According to the present invention, based on the fact that the detection unit detects a change in the operation of the detection target due to the contact between the detection target after the trailing edge of the sheet leaves the detection position and the trailing edge of the sheet, the sheet is It is detected that the sheet has a basis weight larger than the value. For this reason, it is possible to accurately detect a sheet having a larger basis weight than a predetermined value.

1 is a schematic diagram illustrating a printer according to a first embodiment. FIG. (A) The figure which shows the power transmission mechanism of a pick-up roller and a feed roller. (B) The figure which shows the power transmission mechanism of a retard roller. (A) Left side view of the sheet feeding unit. (B) Right side view of the sheet feeding unit. FIG. 2 is a block diagram illustrating a control unit of the printer according to the first embodiment. FIG. 6 is a flowchart showing sheet feeding processing according to the first embodiment. The figure which shows the detection waveform of the encoder at the time of feeding a sheet | seat. The figure which shows the structure of the lifter drive device of an intermediate | middle board. The figure which shows the structure of a seat height sensor. FIG. 9 is a block diagram illustrating a control unit of a printer according to a second embodiment. The figure which shows the detection waveform of the sheet | seat height sensor at the time of feeding a sheet | seat. FIG. 9 is a flowchart showing sheet feeding processing according to the second embodiment. FIG. 10 is a flowchart showing sheet feeding processing according to the third embodiment.

<First Embodiment>
[Schematic configuration of printer]
A printer as an image forming apparatus according to an embodiment of the present invention will be described in detail with reference to the drawings. As shown in FIG. 1, a printer 1 includes a printer main body 2 in which an image forming unit 3 that forms an image on a sheet is housed, and a printer body 2 provided below the printer main body 2, and A sheet feeding unit 5 for feeding.

  The sheet feeding unit 5 includes a sheet cassette 60 serving as a sheet storage unit that stores the sheets S, and a sheet feeding unit 70 that feeds the sheets S stored in the sheet cassette 60. The sheet cassette 60 includes a middle plate 61 as a sheet support device that supports sheets, and a rear end regulating portion 62 that regulates the rear end position of the sheets stacked on the middle plate 61 and the sheet feeding direction. A side restricting portion (not shown) for restricting the position in the width direction orthogonal to is provided.

  On the other hand, the sheet feeding unit 70 includes a pickup roller 71, a separation roller pair 72, and a drawing roller pair 73 in order toward the downstream side in the sheet feeding direction. The pickup roller 71 is a roller that feeds the sheet S from the sheet cassette 60 toward the downstream side in the sheet feeding direction, and abuts against the uppermost sheet S1 of the sheet S and feeds the sheet S1 toward the separation roller pair 72. Further, the separation roller pair 72 constitutes a separation nip 72c that separates and feeds sheets one by one by a feed roller 72a and a retard roller 72b as a feeding rotating body. More specifically, the retard roller 72b is configured to follow the rotation of the feed roller 72a during non-multifeed, and reversely rotate during multifeed to return the multifeed sheet to the sheet cassette 60. The drawing roller pair 73 is provided on the downstream side of the separation roller pair 72 in the conveyance direction, and is a conveyance roller pair that receives the sheet conveyed from the separation roller pair 72 and conveys the sheet to the printer main body 2.

  Further, the drawing roller pair 73 is disposed so that the horizontal distance between the pair of separating rollers 72 and the separating roller pair 72 is shortened in order to reduce the size of the apparatus. Further, since the horizontal distance between the drawing roller pair 73 and the separation roller pair 72 is short, the conveyance path for conveying the sheet fed by the sheet feeding unit 70 is a curved path that is largely curved. Yes. That is, the conveyance guide 74 constituting the conveyance path by guiding the fed sheet is curved with a large curvature. In the present embodiment, the conveyance guide 74 has a curvature radius of, for example, 65 [ mm]. For this reason, the sheet fed from the sheet feeding unit 5 to the printer main body 2 enters into the bottom surface of the printer main body 2 at a substantially right angle. A conveyance sensor 75 is provided immediately after the pair of drawing rollers 73, and the presence or absence of a sheet on the conveyance path is detected by the conveyance sensor 75 as the sheet detection unit.

  On the other hand, the image forming unit 3 includes an image forming unit 3a that forms a toner image on a sheet, a fixing unit 3b that fixes an unfixed toner image formed on the sheet by the image forming unit 3a by heating and pressing, and It has. A toner image is formed on the sheet fed from the sheet feeding unit 5 by the image forming unit 3a, and the toner image is fixed on the sheet by the fixing unit 3b.

  In addition, the printer main body 2 is provided with an input unit 213 (see FIG. 4) and a notification unit 214 that can set information regarding the type of sheet to be fed. Specifically, the input unit 213 is configured by a touch pad of a touch panel provided in the printer main body 2, an input button, and the like, and the notification unit 214 is configured by a liquid crystal unit of the touch panel, a speaker that performs audio output, and the like. ing. A printer control unit 210 (see FIG. 4) that controls the printer main body 2 is a thick paper whose basis weight is larger than that of plain paper (first sheet) on a sheet on which an image is formed based on data input by the input unit 213, for example. If it is determined (second sheet), image forming control for thick paper is executed. Specifically, the image forming unit 3 is controlled so that the sheet conveyance speed is set slower than that of plain paper, or the fixing temperature in the fixing unit 3b is set higher than that of plain paper. . Note that in this embodiment mode, a sheet refers to a thin-layer recording medium such as paper such as paper or an envelope, a plastic film (OHT) for an overhead projector, or a cloth. The cardboard refers to a sheet having a basis weight larger than a predetermined value.

[Drive configuration of sheet feeding unit]
Next, the configuration of the drive train of the sheet feeding unit 70 will be described. FIG. 2A is a diagram showing a driving mechanism for the pickup roller 71 and the feed roller 72a described above. As shown in FIG. 2A, the pick-up roller 71 and the feed roller 72a are configured to be rotated by a feed motor 80 as a drive source. A first drive gear train 81 for transmitting power from the feed motor 80 is interposed.

  The first drive gear train 81 is configured such that a plurality of sets of drive gears are combined, and the rotation from the feed motor 80 is decelerated and transmitted to the pickup roller 71 and the feed roller 72a. An electromagnetic clutch 82 is provided on the route. The electromagnetic clutch 82 is provided on the upstream side in the power transmission direction with respect to the feed shaft 83 that supports the feed roller 72a. When the electromagnetic clutch 82 is engaged and disengaged, the power transmission to the pickup roller 71 and the feed roller 72a is interrupted. You can touch.

  Further, the feed shaft 83 is supported by a one-way clutch 84 interposed between a bearing 85 and a bearing 85 that is non-rotatably supported by the apparatus main body, so that the feed shaft 83 is rotatable in the feeding direction. In the reverse rotation direction opposite to the feeding direction, the rotation is impossible. Further, the feed shaft 83 is provided with a one-way clutch gear 86, and a driving force is transmitted to the pickup roller shaft 87 that supports the pickup roller 71 via the one-way clutch gear 86.

  The one-way clutch gear 86 has a built-in one-way clutch. When the pickup roller 71 is rotated in the feeding direction, power is transmitted, and power is input in a direction in which the feed shaft 83 is rotated in reverse to the feeding direction. When it is done, it is configured to idle. Thereby, only the driving rotation in the feeding direction is input to the pickup roller 71 and the reverse driving force is prevented from being input from the pickup roller 71 to the feed shaft 83.

  Further, the pickup roller 71 is held by a holder 90 so as to be movable up and down, as shown in FIGS. 3 (A) and 3 (B). Specifically, the holder 90 is always pressed downward toward the sheet S by a pressing spring 91 and its raising / lowering position (phase) is adjusted by a cam 92. When the cam 92 rotates toward the phase corresponding to the feeding position, the pickup roller 71 descends about the swing center 94 and contacts the sheet S by the urging force and the own weight of the pressing spring 91. When the cam 92 rotates toward the phase corresponding to the separation position, the pickup roller 71 rises in the direction of the arrow Y3 about the swing center 94 and is separated from the sheet S. Yes.

  On the other hand, the retard roller 72b is also configured to be rotationally driven by a feed motor 80, as shown in FIG. 2B, and between the feed motor 80 and the retard roller 72b, a feed motor is provided. A second drive gear train 101 for transmitting power from 80 is interposed. In the second drive gear train 101, when the feed motor 80 is driven to rotate in a direction in which the pickup roller 71 and the feed roller 72a rotate in the feed direction, the retard roller 72b rotates in a direction opposite to the feed direction. It is configured as follows.

  Further, the second drive gear train 101 includes a torque limiter 102 between the retard shaft 103 and the feed motor 80 that rotatably support the retard roller 72b on the power transmission path. The torque limiter 102 is configured such that power transmission is interrupted when the retard roller 72b comes into contact with the feed roller 72a and the reaction force to the rotational force of the retard roller 72b transmitted from the feed roller 72a increases. The cutoff torque value is set. The cutoff torque value is set to be smaller than the frictional force generated by the friction coefficient between the sheet S and the feed roller 72a. Further, the cutoff torque value of the torque limiter 102 is set to be larger than the frictional force generated between the overlapping sheets.

  When only one sheet S enters the separation nip 72c or when no sheet enters the separation nip 72c, the torque limiter 102 cuts off the power transmission from the feeding motor 80, and the retard roller 72b Rotate with 72a. On the other hand, when two or more sheets enter the separation nip 72c, power transmission is not interrupted by the torque limiter 102, so the retard roller 72b is fed by the driving force from the feeding motor 80. Rotating in the reverse direction, the sheets S are separated one by one.

  In addition, the retard shaft 103 is provided with a code wheel 104, and the rotation of the retard roller 72b can be detected by detecting the rotation of the code wheel 104 by the encoder 105 capable of discriminating the rotation. Yes. Even if the retard roller 72b rotates in the direction opposite to the feeding direction, the feed shaft 83 that supports the feed roller 72a is supported via the one-way clutch 84 described above. There is no reverse rotation. The encoder 105 is a detection unit that detects the behavior of a detection member (hereinafter also referred to as a detection target) that contacts a sheet conveyed along the conveyance path. In the present embodiment, the detection member is The separating roller pair 72, more specifically, the retard roller 72b. In other words, the encoder 105 operates as a detection target related to sheet feeding at a predetermined detection position on the sheet feeding path from the sheet storage unit 60 to the image forming unit 3. It can be said that it is a detection unit that detects. In the present embodiment, the detection position is the position of the separation roller pair 72, more specifically, the separation nip 72c.

[Configuration of control unit]
Next, the control unit 200 of the printer 1 will be described with reference to FIG. The control unit 200 of the printer 1 includes a printer control unit 210 that controls an image forming operation in the printer main body 2, and a feeding control unit 220 that controls sheet feeding in the sheet feeding unit 5. Yes. The printer control unit 210 includes a calculation unit 211 that executes calculation processing related to image formation processing, and a storage unit 212, and the calculation unit 211 is configured by a CPU. The storage unit 212 includes a ROM and a RAM, and the ROM stores various programs necessary for image forming processing such as the program for executing the above-described image forming control for cardboard. ing. The RAM is a work area for the CPU.

  Similarly, the feeding control unit 220 includes a calculation unit 221 that executes a calculation process related to the feeding operation, and a storage unit 222, and the calculation unit 221 includes a CPU. The storage unit 222 includes a ROM and a RAM. The ROM stores, for example, various programs necessary for a feeding process such as a program related to a cardboard determination process described later, and the RAM This is a work area for the CPU. The feeding control unit 220 is connected to the printer control unit 210 via a serial I / F, and is configured to be able to communicate various information with the printer control unit 210. When a sheet feeding instruction is received from the printer control unit 210, a feeding operation corresponding to the instruction is executed.

  In addition to the above-described transport sensor 75, encoder 105, electromagnetic clutch 82, and the like, the feed control unit 220 is connected to a size switch 230, a transport motor 231 and the like. The size switch 230 is a sensor that detects the size of the sheet stored in the sheet cassette 60, and the first switch SW1 to the first switch SW1 to SW1 that are turned on / off according to the positions of the rear end restricting portion 62 and the side restricting portion described above. 5 switch SW5 is provided. As shown in Table 1 below, the sheet size in the sheet cassette 60 is determined according to the on / off states of the first switch SW1 to the fifth switch SW5.

  Further, the calculation unit 221 of the feed control unit 220 is configured to function as a separation rotation detection unit 241, a cardboard determination unit 242, and a system timer 243. The separation rotation detection unit 241 detects the rotation speed of the retard roller 72b by measuring the on / off interval of the signal input from the encoder 105 by the system timer 243. The cardboard determination unit 242 executes cardboard determination processing for determining whether or not the sheet to be fed is cardboard.

[Thick paper judgment processing]
Next, cardboard determination processing by the feeding control unit 220 will be described with reference to FIGS. FIG. 5 is a flowchart showing sheet feeding processing when feeding one sheet. As shown in FIG. 5, when the sheet feeding control unit 220 receives a sheet feeding instruction from the printer control unit 210, the feeding control unit 220 drives the feeding motor 80 (S501). When the rotation speed of the feeding motor 80 is stabilized, the electromagnetic clutch 82 is turned on to rotate the pickup roller 71 and the feed roller 72a, and the pickup roller 71 is lowered to start feeding sheets (S502). .

  When sheet feeding is started, as shown in section 1 of FIG. 6, the uppermost sheet S <b> 1 is fed out by the pickup roller 71 and then conveyed by the separation roller pair 72. In the present embodiment, after the trailing end of the sheet S1 passes, the pickup roller 71 sends out the sheet S2 following the sheet S1. As a result, the leading edge of the sheet S2 tries to enter the separation nip 72c while the sheet S1 is being conveyed by the separation roller pair 72. Then, as shown in section 2 in FIG. 6, the retard roller 72 b rotates in the direction opposite to the feeding direction to separate the sheets S one by one, so that the waveform detected by the encoder 105 is different from that in section 1. To turn it on / off. Hereinafter, this operation is referred to as advance feeding.

  The feeding control unit 220 functions as the above-described separation rotation detection unit 241 during sheet feeding, and detects the rotation speed of the retard roller 72b. Then, as described above, in section 2 in FIG. 6, when the rotational speed of the retard roller 72 b becomes a predetermined value or less, the electromagnetic clutch 82 is turned off, and the pickup roller 71 and the feed roller 72 a are switched to the driven rotation. Further, the pickup roller 71 is separated from the sheet S (S503). In this way, with the leading edge of the succeeding sheet S2 trying to enter the separating nip 72c of the separating roller pair 72, the leading edge position of the succeeding sheet S2 is set in the separating nip 72c by separating the pickup roller 71 from the succeeding sheet S2. Aligned to the front position. In the present embodiment, when the conveyance speed of the sheet S1 in the section 1 is 700 [pps], the predetermined value is half of the conveyance speed in the section 1, such as 350 [pps] which is half of the predetermined value. The following values are set.

  In this way, by aligning the leading end position of the sheet S2 with the position in front of the separation nip 72c, the distance between the sheets S1 and S2 (the interval between the trailing end of the sheet S1 and the leading end of the sheet S2) can be shortened. . Hereinafter, this reason will be described. If the sheet S2 is not fed in advance, a frictional force may be exerted between the sheets S1 and S2 when the sheet S1 is conveyed, and the sheet S2 may be taken out. That is, after the sheet S1 is completely fed, the leading end position of the sheet S2 may vary from the initial position stacked on the sheet cassette 60 to the separation nip 72c. Therefore, it is necessary to provide at least the sheet feeding variation between the sheets S1 and S2. According to the present embodiment, by performing the preceding paper feeding using the encoder 105, it is possible to shorten the space between the sheets S1 and S2.

  When the electromagnetic clutch 82 is turned off and the succeeding sheet S2 is returned to a position before the separation nip 72c by the reverse rotation of the retard roller 72b, the retard roller 72b rotates following the conveyance of the preceding sheet S1. At this time, the waveform detected by the encoder 105 approaches a waveform that is turned on / off according to the conveyance speed of the sheet S1 as in section 1. In this state, the feeding control unit 220 stands by until a state immediately before the trailing end of the sheet S1 passes through the separation nip 72c (S504).

  That is, the feeding control unit 220 waits for the sheet S1 to be conveyed in the feeding direction by a distance corresponding to the sheet size detected by the size switch 230. In the present embodiment, as the distance before the trailing edge of the sheet passes through the separation nip 72c, the sheet waits for a distance less than the size detected by the size switch 230. For example, if the size detected by the size switch 230 is 215.9 [mm] of the LTR-L size, the waiting time is 210.9 [mm].

  When the trailing edge of the sheet S1 passes through the separation nip 72c as in section 3 in FIG. 6, the retard roller 72b gradually stops together with the feed roller 72a that has been rotated following the conveyance of the sheet S1. For this reason, the waveform detected by the encoder 105 gradually increases the OFF / ON interval.

  Here, when the feeding control unit 220 waits for the sheet to be conveyed in the feeding direction by a distance corresponding to the sheet size detected by the size switch 230, the rotation speed of the retard roller 72b is then set for a predetermined time. Then, it waits until it becomes a predetermined value or less (S505). The fixed time is, for example, 20 [ms], from the state in which the retard roller 72b is rotated in the reverse direction in the paper feeding direction in step S503 to return to the normal rotation in the paper feeding direction by the conveyance of the sheet S1. It is time to consider. The predetermined value is a value equal to or smaller than the predetermined value in S503, for example, if the predetermined value in Step S503 is 350 [pps], that is, 175 [pps], which is half of that value. That is, the feeding control unit 220 waits for the trailing edge of the fed sheet S1 to exit the separation nip 72c in steps S504 and S505.

  Then, when the predetermined time of step S505 has elapsed, the feeding control unit 220 functions as the above-described thick paper determination unit 242 and determines whether or not the sheet S1 being fed is thick paper (S506). Specifically, the feeding control unit 220 determines that the sheet S1 is thick paper when the rotational speed of the retard roller 72b is equal to or greater than a predetermined value for a certain period of time.

  Normally, when the trailing edge of the sheet S1 passes through the separation nip 72c, the above-described feed roller 72a and retard roller 72b stop rotating. Therefore, the rotation of the roller is not detected in the subsequent sections 4 and 5 as in the waveform detected by the encoder 105 when the plain paper in FIG. 6 is fed. However, when feeding thick paper, as shown in section 4 of FIG. 6, after the trailing end of the sheet S1 passes through the separation nip 72c, the retard roller 72b is hit by the stiffness of the sheet. That is, as described above, in the sheet feeding unit 5, the conveyance path is formed with a large curvature from the sheet cassette 60 toward the bottom surface of the printer main body 2. For this reason, the leading edge of the sheet that has passed through the separation nip 72c is nipped and conveyed by the drawing roller pair 73, and the sheet is curved along a curved conveyance path. In this state, when the trailing edge of the sheet passes through the separation nip 72c, the trailing edge of the sheet jumps due to the restoring force caused by the stiffness (rigidity) of the sheet, and the retard located on the outer diameter side in the curvature of the conveyance path Strike the roller 72b. Then, the retard roller 72b vibrates around the oscillation center 106 due to the impact, and the waveform detected by the encoder 105 at this time repeats off / on irregularly as compared with the case where it gradually stops.

  Since plain paper is weaker than thick paper, even if the retard roller 72b is struck at the trailing edge of the sheet, the encoder 105 is irregularly turned off so that the above-described conveyance speed becomes a predetermined value or more. An irregular waveform indicating repetition of / on is not detected. In step S505, the feeding control unit 220 detects the trailing edge of the sheet due to the stiffness of the thick paper by detecting the irregular waveform, and determines that the paper is thick based on the irregular waveform. Note that the fixed time in step S505 is an interval in consideration of variation in behavior of the encoder 105 in the section 4 and the subsequent section 5, such as 10 [ms].

  Thereafter, as shown in the section 5 in FIG. 6, as the vibration of the retard roller 72b converges, the waveform of the encoder 105 is either stopped and turned off or turned on while the off / on interval becomes longer. Stick to. In addition, when the cardboard determination is finished, the feeding control unit 220 stops the feeding motor 80 (S507) and ends the feeding operation. The feeding control unit 220 may determine that the sheet is thick paper if the rotational speed of the retard roller 72b in step S505 is sufficiently larger than the predetermined value. For example, if the predetermined value in step S505 is 175 [pps], the sufficiently high speed is a rotational speed considering the behavior variation of the encoder 109, such as a value of 262 [pps] that is 1.5 times the predetermined value.

  When the cardboard control process is executed by the feeding control unit 220, the determination result is communicated to the printer control unit 210. The printer control unit 210 compares the sheet information stored in the storage unit 212 with the determination result of the cardboard determination process, and if both the results match, the fed sheet is The image forming process is executed assuming that the sheet is thick paper. If the two results do not match, the image forming process is not executed and the notification unit 214 is controlled to notify the user that the sheet type is different as a sheet type error. . Here, the sheet information stored in the storage unit 212 is paper type information (plain paper, thick paper, thin paper, etc.) of the sheet S designated in advance by the user when issuing a print instruction.

  Further, when the paper type of the sheet S is not designated in advance by the user, the feeding control unit 220 performs a thick paper determination process on the first sheet S1 of the job. Then, the fixing temperature in the fixing unit 3b when fixing the image on the subsequent second sheet S2 may be changed according to the determination result of the thick paper determination processing. Further, if the leading edge of the sheet S1 has not yet reached the fixing unit 3b at the timing when the trailing edge of the sheet S1 passes through the separation nip 72c and the thick paper determination process is completed, according to the determination result of the thick paper determination process, The fixing temperature for the sheet S1 may be changed.

  In the present embodiment, the operation at the time of printing one sheet is shown, but the above-mentioned cardboard determination process can be executed even at the time of printing a plurality of sheets. For example, before step S507 in FIG. 5, after a feeding interval satisfying the throughput defined for each sheet size is provided, steps S502 to S506 are repeatedly performed until the final sheet is fed. Accordingly, the invention described in this embodiment can be applied to a plurality of prints.

  When the stiffness of the sheet is different as in the above-described thick paper and thin paper, the restoring force generated upon returning from the curved state is different. In the present embodiment, when a sheet having a basis weight larger than a predetermined value is fed, the detection waveform of the detection unit after the trailing edge of the sheet leaves the detection position due to the difference in restoring force, It has been noted that a different predetermined waveform, that is, a specific irregular waveform is detected. In other words, in the present embodiment, the irregular waveform is detected by the detection unit when the detection target changes due to contact between the detection target after the trailing edge of the sheet leaves the detection position and the trailing edge of the sheet. I believe that. In other words, the irregular waveform is detected by the detection unit that the behavior of the detection member has changed due to the trailing edge of the sheet fed by the sheet feeding unit 70 contacting the detection member. I believe that. In the case of a sheet with weak stiffness, it is considered that a remarkable change does not appear in the detection result of the detection unit even if the contact is made due to the low restoring force. For this reason, it is possible to determine whether or not the basis weight of the fed sheet is greater than or equal to a predetermined basis weight based on the irregular waveform after the trailing edge of the sheet exits the detection position as described above. it can.

  More specifically, in the present embodiment, an encoder 105 that detects the rotation state of the separation roller pair 72, specifically, the rotation speed of the retard roller 72b, is used as the detection unit. The feeding control unit 220 detects that a change in the rotation state of the separation roller pair 72 has been detected in a predetermined period after the trailing edge of the sheet has passed through the separation nip 72c, so that the fed sheet is thick paper. Judging that there is. In other words, in the present embodiment, when the feeding control unit 220 detects a waveform in which the rotational speed of the retard roller 72b is greater than a predetermined value in the section 3 described above, the fed sheet is cardboard. Judging that there is. As described above, the thick paper can be detected with high accuracy by the change in the rotation speed of the pair of separation rollers 72 caused by the stiffness of the sheet which is not related to the change in the transportability. Further, since the encoder 105 which is a sensor used in the sheet feeding operation is used, the cost is not increased.

<Second Embodiment>
Next, a second embodiment will be described with reference to FIGS. Note that the present embodiment is different from the first embodiment in that sheet thick paper determination processing is performed using a sheet height sensor. For this reason, the description of the same configuration as that of the first embodiment is omitted.

  As shown in FIG. 7, the intermediate plate 61 is provided so as to be connectable to a lifter driving device 602 via a lift arm 601. The lifter driving device 602 is a lift part that raises the middle plate 61 as a support means and adjusts the height position of the seat, and the drive part includes a gear 608 and a lift motor 609 (see FIG. 9). It is configured. When the lift motor 609 is driven, the middle plate 61 is moved upward (lifted up) by driving a gear 607 provided in the sheet cassette 60 and a half-moon gear 606 connected to the lift arm 601. It has become.

  As shown in FIG. 8, the sheet cassette 60 is provided so that it can be pulled out when the sheet bundle S is stacked. When the sheet cassette 60 is pulled out from the sheet feeding unit 5, the connection with the lifter driving device 602 is released, whereby the intermediate plate 61 is lowered to the lowest position by its own weight.

  As shown in FIG. 7, the sheet feeding unit 5 is provided with an intermediate plate detection switch 604 for detecting that the intermediate plate 61 has been raised to a certain height. When the intermediate plate 61 is on the lower side, the intermediate plate detection switch 604 is turned on when the switch portion is pushed by the intermediate plate detection flag 603. Further, when the intermediate plate 61 is raised by the lifter driving device 602 and the flag contact portion 605 of the intermediate plate 61 contacts the intermediate plate detection flag 603 to rotate the intermediate plate detection flag 603, the intermediate plate detection flag 603 The portion where the switch part of the middle plate detection switch 604 is pressed also rotates. Then, due to the rotation of the intermediate plate detection flag 603, the signal of the intermediate plate detection switch 604 is switched off. The lift-up after the opening / closing of the sheet cassette 60 is performed by raising the middle plate 61 to a position where the middle plate detection switch 604 is turned off.

  Further, reference numeral 702 shown in FIG. 8 denotes a sheet height sensor which is turned on when the uppermost sheet S1 of the stacked sheets S pushes up the sheet height flag 703 to be shielded from light, and the sheet height flag 703 is lowered. It turns off when it becomes translucent. The height of the middle plate 61 during printing is controlled so that the signal of the sheet height sensor 702 is ON, that is, the position where the sheet can be fed is maintained. In the present embodiment, the sheet height sensor 702 is a height detection unit that detects the height position of the sheets stacked in the sheet storage unit. In the present embodiment, the detection unit is formed by the sheet height sensor 702, and the position where the sheet height flag 703 contacts the sheet on the intermediate plate 61 is the detection position. The sheet on the intermediate plate 61 is a detection member (detection target).

  Next, the configuration of the control unit according to the present embodiment will be described with reference to FIG. As shown in FIG. 9, the feeding control unit 220 </ b> A according to the present embodiment also functions as a lift-up determination unit 801 and a lift-up unit 802 in addition to functioning as the cardboard determination unit 303 and the system timer 305. That is, the feeding control unit 220A is configured to be able to execute lift-up control of the intermediate plate 61 by controlling the lifter driving device 602. The lift-up determination unit 801 determines lift-up after opening / closing of the sheet cassette 60 and execution of lift-up when the sheet height sensor 702 is turned off during printing.

  Further, when the lift-up determination unit 801 determines that the lift-up is necessary, the lift-up unit 802 performs the lift-up of the intermediate plate 61. In the case of lift-up after the opening and closing of the sheet cassette 60, the lift-up means 802 drives the lift motor 609 to a position where the middle plate detection switch 604 is turned off. In the case of lift-up when the sheet height sensor 702 is turned off during printing, the lift-up means 802 can drive the lift motor 609 for a predetermined time (for example, 30 [ms]) to feed the height of the paper surface. Maintain the correct position.

  Next, the cardboard determination process according to the present embodiment will be described with reference to FIGS. FIG. 10 is a diagram illustrating waveforms of detection signals of the sheet height sensor 702 when plain paper and thick paper are fed. As shown in FIG. 10, in section 1, the electromagnetic clutch 82 is turned on, the pickup roller 71 is lowered and is in contact with the uppermost sheet S1, and the sheet S1 is fed by the pickup roller 71 and the feed roller 72a. Being conveyed in the direction. At this time, the sheet height sensor 702 is in contact with the sheet S1 and turned on. If the seat height sensor 702 is turned off in this section, the feeding control unit 220A determines that the lift-up process is necessary, and lifts up the intermediate plate 61.

  In section 2, the electromagnetic clutch 112 is turned off and the pickup roller 71 is separated from the sheet S1. For this reason, the sheet S1 is conveyed in the feeding direction by the drawing roller pair 73, and the pickup roller 71 and the feed roller 72a rotate following the conveyance of the sheet S1. At this time, the seat height sensor 702 is turned on. However, comparing the case of feeding plain paper with the case of feeding thick paper, when the thick paper is fed due to the stiffness of the sheet, the middle plate 61 on which the sheets S are stacked feeds plain paper. It will be in a depressed state than if it is.

  Section 3 shows a case where the trailing edge of the sheet S1 has passed through the sheet height flag 703, and particularly in this drawing, a thick sheet is being fed. In the section 3, the pressing force from the sheet due to the bending of the sheet S <b> 1 is received more strongly than in the section 2. Here, normally, when the plain paper is fed, the stiffness of the sheet is not as strong as that of the thick paper. Therefore, the intermediate plate 61 is not pushed down to the extent that the detection of the sheet height sensor 702 is affected. However, when the thick paper is being fed, the middle plate 61 is further pushed down from the state of the section 2, and accordingly, the sheet height flag 703 is further lowered, and the sheet height sensor 702 is turned off.

  A section 4 represents the position where the sheet S1 has passed through the separation nip 72c of the pair of separation rollers 72. When the trailing edge of the sheet leaves the sheet cassette 60 and passes through the separation nip 72c, the pressed middle plate 61 returns to the original position. Further, since the sheet feeding unit also returns from the pushed-up state, the sheet height flag 703 is raised to the same position as when plain paper is fed, and the sheet height sensor is turned on.

  FIG. 11 is a flowchart illustrating the sheet feeding process according to the present embodiment. As illustrated in FIG. 11, the feeding control unit 220 </ b> A performs sheet feeding processing from step S <b> 501 to step S <b> 504 in the same manner as in the first embodiment. In step S504, the sheet size is fed by the length according to the sheet size, and the lift-up execution determination for maintaining the height of the paper surface and the lift-up operation are simultaneously executed.

  When step S504 is executed, the feeding control unit 220A then executes a cardboard determination process (S601). Specifically, the feeding control unit 220A determines that the sheet is cardboard when the sheet height sensor 702 has been turned off for a predetermined time. The predetermined time is a time that takes into account tolerances of the sheet height sensor 702, the sheet height flag 703, and the sheet feeding unit 70, such as 10 [ms].

  In this embodiment, the operation for printing one sheet is shown, but a plurality of prints may be printed. When the present invention is applied to a plurality of prints, for example, after a feeding interval satisfying the throughput defined for each sheet size is provided, steps S502 to S504 and S601 are repeated until the final sheet feeding is completed. good.

  As described above, during the sheet feeding, the sheet feeding control unit 220A has the sheet height position lower than the predetermined height position in a period other than the timing for performing the lift-up control execution determination. Based on the above, it is determined that the fed sheet is cardboard. That is, in the present embodiment, the sheet height sensor 702 is used as a detection unit, and an irregular waveform is detected in the detection waveform of the sheet height sensor 702 after the trailing edge of the sheet passes through the sheet height flag 703. Based on this, it is determined that the sheet is cardboard.

<Third Embodiment>
Next, a third embodiment will be described with reference to FIG. Note that the present embodiment is different from the first embodiment in that the thick paper determination control that can improve the accuracy of the thick paper determination is executed when printing a plurality of sheets. It is different from the form. Accordingly, only the points different from the first embodiment will be described below, and descriptions of other points will be omitted.

  The feeding control unit 220 detects the size of the fed sheet and whether or not the sheet has been normally conveyed by the conveyance sensor 75 described above. Specifically, the feeding control unit 220 sets the length of the fed sheet in the feeding direction to the sheet fed by the conveyance sensor 75 to the conveyance speed [mm / s] of the drawing roller pair 73. It is obtained by multiplying the detection time [s]. In addition, the feeding control unit 220 determines whether or not the conveyance sensor 75 detects the leading edge of the sheet within a predetermined time from the start of feeding, and the conveying sensor within a predetermined time after detecting the leading edge of the sheet. It is determined whether or not the sheet 75 has been removed. Based on this result, it is determined whether or not the sheet has been normally conveyed.

  In the present embodiment, the predetermined time from the start of feeding is (transport distance [mm] +50 [mm] from the sheet leading edge position of the sheet cassette 60 to the transport sensor 75) / extraction roller pair. It is calculated by the conveyance speed [mm / s] of 73. Note that 50 [mm] is a margin in consideration of variations in conveyance. Further, a predetermined time after the leading edge of the sheet reaches the conveyance sensor 75 is (paper size detected by the size switch 230 [mm] +50 [mm]) ÷ conveying speed of the drawing roller pair 73 [mm / s]. Sought by.

  FIG. 12 is a flowchart illustrating sheet feeding processing when feeding a plurality of sheets. The feeding control unit 220 determines thick paper from the results of a plurality of sheets (S701) after the rotation speed of the retard roller 72b becomes equal to or lower than a predetermined value after starting the conveyance of the sheet (S501). For example, the feeding control unit 220 determines the time when the maximum value and the rotational speed of the retard roller 72b detected between step S505 and the next sheet feeding are equal to or greater than the values determined in step S505. Remember for each sheet.

  Then, after feeding a predetermined number of sheets, for example, three sheets, the average of the stored maximum value of the rotation speed and the time when the rotation speed is equal to or greater than the value determined in step S505 is taken, and the step is performed based on that value The cardboard judgment performed in S701 is performed. That is, the feeding control unit 220 determines whether or not the paper is thick paper based on the detection results of the fed multiple sheets. Thus, by determining the thick paper based on the information of a plurality of sheets, it is possible to accurately determine the thick paper even when the stiffness of the sheet varies. Note that the predetermined number of sheets to be determined here may be any number as long as it is two or more.

  If the sheet size detected by the size switch 230 and the actual sheet size detected by the conveyance sensor 75 are different from each other by a predetermined amount or more, there is a possibility that the thick paper is erroneously determined by double feeding of sheets. Furthermore, when the conveyance sensor 121 is not normally conveyed, there is a possibility that the thick paper is erroneously determined as the conveyance failure paper.

  For this reason, the sheet feeding control unit 220 determines that the sheet size does not match (Yes in S702) or that the sheet is not normally conveyed based on the detection result of the conveyance sensor 75 (Yes in S703). To reject the cardboard judgment result. Thereby, it is possible to accurately determine the thick paper. Note that the predetermined amount in step S702 is a value sufficiently larger than the deviation considering the tolerance of the rear end regulating portion 62, for example, 5 [mm].

  In step S705, if the feed control unit 220 receives the next paper feed designation from the printer control unit 210, the process proceeds to step S706, and if not, the process proceeds to step S507. In step S706, a time is waited so that the feeding interval satisfies a desired throughput. When the feeding timing comes, the process proceeds to step S502, and feeding is started.

  In this way, by determining the thick paper based on the information of a plurality of sheets, it is possible to accurately determine the thick paper even when the stiffness of the sheet varies. Also, if the paper size specified by the size detector and the actual paper size detected by the transport detector are different, or if the transport detector cannot detect the normal transport of the paper, it is possible to accurately reject the thick paper judgment. The cardboard can be judged.

  In this embodiment, the case where a plurality of sheets are printed in the method described in the first embodiment has been described. However, the case where a plurality of sheets are printed in the method described in the second embodiment is described. However, the present invention is applicable. In this case, step S505 in FIG. 12 is not performed, and the off time of the sheet height sensor 702 is stored for each sheet from step S504 to the next sheet feeding in step S701. Then, after feeding a predetermined number of sheets, for example, three sheets, the stored sheet height sensor 702 is averaged for the off time, and the cardboard judgment performed in step S601 may be performed based on the average value. Note that the predetermined number of sheets to be determined here may be any number as long as it is two or more.

  In this embodiment, the conveyance sensor 75 provided in the sheet feeding unit 5 is used. However, a sensor attached to the printer main body 2 may be used. In this case, the printer control unit 210 notifies the feeding control unit 220 of the actual sheet size and whether or not the sheet has been normally conveyed.

  Furthermore, in the above-described embodiment, the separation nip 72c is configured using the retard roller 72b. For example, instead of the retard roller 72b, the separation is stopped when a plurality of sheets enter the separation nip 72c. A roller may be used. That is, any separation rotating body that can separate the sheets one by one when a plurality of sheets enter the separation nip 72c may be used.

  In the first embodiment, the encoder 105 that detects the rotation of the retard roller 72b is used as a detection unit. For example, a sensor that detects the rotation of another roller on a curved conveyance path is used as the detection unit. It may be used. In addition, in the above-described embodiment, cardboard detection based on irregular waveform detection is used for reporting a sheet type error. For example, when cardboard is detected, image formation control is switched for cardboard, etc. It may be used to change the formation control.

  In the above-described embodiment, the size switch 230 attached to the sheet feeding unit 5 is the size detection unit. However, the sheet size notified from the printer control unit 210 to the feeding control unit 220 may be used. In that case, the user can designate the sheet size set in the sheet cassette 60 from the input unit 213 of the printer main body 2, and this input unit 213 functions as a size detection unit.

  Furthermore, in the above-described embodiment, the printer control unit 210 and the feeding control unit 220 are configured as separate control units, but may be a single control unit. Further, although the printer body 2 and the sheet feeding unit 5 are separate units, they may be integrated. In addition, in the above-described embodiment, the laser beam printer is taken as an example, but the present invention may be applied to an image forming apparatus such as an ink jet printer or a copying machine.

60: Sheet storage unit (sheet cassette), 70: Sheet feeding unit, 72: Separating roller pair, 74: Conveyance path (conveyance guide), 75: Sheet detection unit (conveyance sensor), 105, 702: Detection unit (encoder) , Seat height sensor), 200: control unit, 214: notification unit, 230: size detection unit (size switch), 602: lift unit (lifter driving device)

Claims (9)

A sheet storage section for storing the sheet;
A sheet feeding unit for feeding sheets stored in the sheet storage unit;
A curved conveyance path for guiding the sheet fed by the sheet feeding unit;
A detection unit that detects the behavior of the detection member that comes into contact with the sheet conveyed along the conveyance path;
Based on the fact that the detection unit has detected that the behavior of the detection member has changed due to the trailing edge of the sheet being fed by the sheet feeding unit being in contact with the detection member, the sheet feeding unit A control unit that determines that the fed sheet is a sheet having a basis weight larger than a predetermined value,
A sheet feeding apparatus characterized by that. The sheet feeding unit includes a separation rotator that forms a separation nip together with a feeding rotator for separating and feeding sheets to be fed one by one,
The detection unit is a detection unit that detects a rotation state of the separation rotating body,
The control unit determines whether the fed sheet is based on the detection of the change in the rotation state of the separation rotator in a predetermined period after the trailing edge of the sheet passes through the separation nip. It is determined that the sheet has a basis weight larger than the predetermined value.
The sheet feeding apparatus according to claim 1, wherein The sheet storage unit includes a support unit that supports a sheet, and a lift unit that raises the support unit and adjusts the height position of the sheets stacked on the sheet storage unit,
The detection unit is a detection unit that detects the height position of the sheets stacked in the sheet storage unit,
The control unit is configured to hold the height position of the sheet at the feeding position based on the fact that the height position of the sheet detected by the detection unit is lower than a predetermined height position. Based on the fact that the height position of the seat is lower than the predetermined height position in a period other than the timing at which the execution determination of the lift-up control is performed. , Determining that the fed sheet is a sheet having a larger basis weight than the predetermined value;
The sheet feeding apparatus according to claim 1, wherein The control unit is a sheet having a basis weight larger than the predetermined value, based on a detection result of the detection unit in a plurality of fed sheets. To determine whether or not
The sheet feeding apparatus according to claim 1, wherein the sheet feeding apparatus is a sheet feeding apparatus. A sheet detector for detecting the presence or absence of a sheet on the transport path;
The control unit detects the detection unit when the stored sheet size of the sheet stored in the sheet storage unit is different from the sheet size detected based on the detection result of the sheet detection unit. Based on the result, the sheet is not judged to be a sheet having a larger basis weight than the predetermined value.
The sheet feeding apparatus according to claim 1, wherein the sheet feeding apparatus is a sheet feeding apparatus. A sheet feeding device according to any one of claims 1 to 5,
An image forming unit that forms an image on a sheet fed by the sheet feeding device;
An informing unit for informing that the type of sheet is different,
The control unit controls the notification unit when the stored sheet type stored in the sheet storage unit is different from the sheet type determined based on the detection result of the detection unit. Notify that the seat type is different,
An image forming apparatus. A sheet storage section for storing the sheet;
A sheet feeding unit for feeding sheets stored in the sheet storage unit;
A curved conveyance path for guiding the sheet fed by the sheet feeding unit;
A detection unit that detects the behavior of the detection member that comes into contact with the sheet conveyed along the conveyance path;
An image forming unit that forms an image on the sheet fed by the sheet feeding unit;
An informing unit for informing that the type of sheet is different;
In the case where it is set that a sheet having a basis weight smaller than a predetermined value is stored in the sheet storage unit, the trailing edge of the sheet fed by the sheet feeding unit contacts the detection member A control unit that controls the notification unit to notify that the type of the sheet is different based on the fact that the detection unit has detected that the behavior of the detection member has changed.
An image forming apparatus. The sheet feeding unit includes a separation rotator that forms a separation nip together with a feeding rotator for separating and feeding sheets to be fed one by one,
The detection unit is a detection unit that detects a rotation state of the separation rotating body,
The control unit controls the notification unit based on the detection of the change in the rotation state of the separation rotator during a predetermined period after the trailing edge of the sheet has passed through the separation nip. To inform you that the seat type is different,
The image forming apparatus according to claim 7. The sheet storage unit includes a support unit that supports a sheet, and a lift unit that raises the support unit and adjusts the height position of the sheets stacked on the sheet storage unit,
The detection unit is a detection unit that detects the height position of the sheets stacked in the sheet storage unit,
The control unit is configured to hold the height position of the sheet at the feeding position based on the fact that the height position of the sheet detected by the detection unit is lower than a predetermined height position. Based on the fact that the height position of the seat is lower than the predetermined height position in a period other than the timing at which the execution determination of the lift-up control is performed. , Notifying that the type of sheet is different by controlling the notification unit,
The image forming apparatus according to claim 7.

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