JP2009298525A - Image forming device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To enhance operability when forming images in a plurality of sheets by easily confirming images formed on sheets by discharging the first several sheets to the vicinity of an operation part. <P>SOLUTION: When the plurality of image forming parts are inputted into the operation part 140 in this image forming device 1, a reversing passage 170a is selected as a switching member 175, a prescribed number of sample sheets can be discharged from a preliminary discharge passage 190 by making sheets pass through a both-side conveying passage 174, a paper feed conveying passage 149, a sheet conveying passage 111 and a switching member 195. An outlet 190a of the preliminary discharge passage is arranged at a position near the operation part 140. A user can confirm images of the sample sheets near the operation part 140 and is not required to unnecessarily move. As a result, the image confirming operation can be efficiently performed. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image forming apparatus that improves the operability of a user by creating a plurality of image forming sheets by ejecting some of the first copies in the vicinity of an operation unit for inputting operation information for content confirmation. .

  Image forming apparatuses such as copiers and printers that form images on sheets, and multi-function machines that have these combined functions, such as bookbinding processing and punching processing, that process sheets on which images are formed in the main body of the apparatus A sheet processing apparatus capable of performing various processing may be provided. In recent years, sheet processing apparatuses have been provided with various processing functions, tending to increase in size, and as a result, the overall size of the image forming apparatus has become a cause.

  Further, in the conventional image forming apparatus, when there is no need to process a sheet on which an image is formed, the sheet processing apparatus directly discharges the sheet to the tray without performing the sheet processing (see Patent Document 1). .

JP-A-8-101545

  By the way, when a user creates a plurality of image forming sheets with the image forming apparatus, it is possible to confirm whether or not an image is formed as desired on the sheet by discharging the first few sheets to the tray. is there. However, in the image forming apparatus described in Patent Document 1, when the sheet processing apparatus becomes large, the position of the tray becomes far from the operation unit that inputs operation information of the image forming apparatus, and the information input operation to the operation unit and the tray The confirmation operation of the upper sheet became troublesome and sometimes difficult to use.

  In the case of creating a plurality of image forming sheets, the present invention discharges some of the first copies to the vicinity of the operation unit, making it easy to check the image formed on the sheet, and improving the operability. To provide an apparatus.

  An image forming apparatus according to the present invention includes an image forming unit that forms an image on a sheet, a stacking unit that stacks a sheet on which an image is formed by the image forming unit, and a sheet on which an image is formed by the image forming unit. A preliminary discharge unit for conveying a sheet to the outside from between the image forming unit and the stacking unit, a selection unit for selecting the stacking unit and the preliminary discharge unit, an operation unit for inputting the number of image forming units, When the sample mode for discharging and confirming the first predetermined number of sheets on which image formation has been performed is selected from among the plurality of image forming copies input to the operation unit, the selection is performed so that the sheets are conveyed to the preliminary discharge unit. Control means for causing the means to select the preliminary discharge means, and the outlet of the preliminary discharge means is disposed at a position closer to the operation portion than the loading means.

  An image forming apparatus according to the present invention includes an image forming unit that forms an image on a sheet that has been transported through a transport path that transports the sheet, a stacking unit that stacks a sheet on which an image is formed by the image forming unit, and an image A refeed path for transporting the formed sheet from between the image forming unit and the stacking means to the transport path; a refeed selection means for selecting the stacking means and the refeed path; A preliminary discharge path that branches from the conveyance path between the junction point of the refeed path and the conveyance path and the image forming unit and conveys a sheet to the outside; the image forming unit and the preliminary discharge path; A discharge selection means for selecting the image, an operation unit to which the number of image forming copies is input, and a sample for discharging and confirming the first predetermined number of sheets on which image formation has been performed among the plurality of image forming copies input to the operation unit When the mode is selected, the sheet Control means for causing the refeed selection means to select the refeed path and for causing the discharge selection means to select the preliminary discharge path for transporting to the preliminary discharge path, The outlet is arranged at a position closer to the operation unit than the loading means.

  In the image forming apparatus of the present invention, when there are a plurality of image forming copies input to the operation unit, the first predetermined number of sheets on which the image has been formed is operated as a sample sheet for image formation confirmation from the outlet of the preliminary discharge means. It can be discharged near the section.

  For this reason, the image forming apparatus according to the present invention does not require the user to check the stacking means located at a position distant from the operation unit when the user checks the image on the image formation confirmation sheet. Well done.

  The image forming apparatus of the present invention corrects an image when the user wants to correct the image as a result of checking the image on the image formation confirmation sheet because the operation unit is located near the image formation confirmation sheet. It can be done efficiently.

  Thus, the image forming apparatus of the present invention can improve operability.

  Hereinafter, an image forming apparatus according to an embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is a schematic cross-sectional view along the sheet conveying direction of an image forming apparatus according to an embodiment of the present invention.

  The image forming apparatus 1 includes an image input device (hereinafter referred to as “reader unit”) 120, an image output device (hereinafter referred to as “printer unit”) 110, a sheet processing device (finisher) 2, and a preliminary discharge tray. 130 and an external sheet feeding device 3.

  As shown in FIGS. 4 and 5, the image forming apparatus 1 can input various mode settings and information necessary for image formation in the vicinity of the preliminary discharge tray 130, and display the operation state of the image forming apparatus. The operation unit 140 is provided. Information necessary for image formation includes the number of sheets on which an image is formed, the size of the sheet, and whether the image is formed on one side or both sides.

  The image forming apparatus is operated by a CPU 199 (FIG. 3) as a control unit that controls the operation of the reader unit 120, the printer unit 110, the sheet processing apparatus 2, and the like based on a predetermined program in accordance with the set operation mode. It has become.

  The reader unit 120 reads a document and converts it into image data. The printer unit 110 has a plurality of cassettes 145, and forms a toner image as a visible image on a sheet of image data by a print command. The sheet processing apparatus 2 is configured to bind sheets in a bundle with a stapler 270. The external sheet feeding device 3 feeds a large amount of sheets to the printer unit 110. The preliminary discharge tray 130 is configured such that processed sheets are discharged and stacked by switching the discharge path.

  The reader unit 120 includes a document feeding device 120A and a document reading device 120B. The document feeder 120A automatically feeds documents stacked on the document tray 129 one by one onto the document table glass 121 of the document reading device 120B. The document reading device 120 </ b> B is configured to read a document sent onto the document table glass 121.

  The document passes over the stopped scanner unit 122 while sliding on the document table glass 121 of the document reading device 120B. At this time, the lamp 123 of the scanner unit 122 is turned on to irradiate the original. The reflected light of the original is reflected by the mirrors 124, 125, and 126, passes through the lens 127, and then is input to the CCD image sensor unit 128. The CCD image sensor unit 128 photoelectrically converts the input image information and converts it into an electrical signal. The converted electrical signal is subjected to various types of image processing and then input to the printer unit 110 to be visualized and formed as a toner image on the sheet.

  Note that the electrical signal input to the printer unit 110 may be image data transmitted from a personal computer or a fax machine in addition to the document reading device 120B, and is limited to the signal from the document reading device 120B. is not.

  The electrical signal input to the printer unit 110 is converted into an optical signal by the exposure control unit 101 and irradiated onto the photosensitive drum 102 in accordance with the image signal. The latent image formed on the photosensitive drum 102 by the irradiation light is developed with toner by the developing unit 103 to become a toner image.

  On the other hand, the sheets stacked on the cassette 145 are sequentially sent out from the cassette 145 by the paper feeding unit 146. The fed sheet is conveyed to the registration roller pair 148 by the vertical path roller pair 147. At this time, the registration roller pair 148 stops rotating.

  The sheet conveyed to the registration roller pair 148 is received by the registration roller pair 148 to form a loop (deflection), and the skew is corrected. As a result, the leading edge of the sheet is corrected in parallel with the axis of the photosensitive drum 102.

  Thereafter, the registration roller pair 148 rotates at a predetermined timing to transfer the sheet to the photosensitive drum 102 at a timing at which the toner image already formed on the photosensitive drum 102 can be transferred to a predetermined position in the sheet conveyance direction. It sends in between the part 104.

  In the transfer unit 104, an endless transfer belt 105 is wound around a driving roller 106 and a driven roller 107, and a transfer corona charger 108 is disposed on the inner side of the transfer belt 105 facing the photosensitive drum 102. Has been configured. Thereby, the transfer belt 105 sucks and conveys the sheet. While the sheet is conveyed to the transfer belt 105, the toner image is transferred from the photosensitive drum by the corona charger 108.

  The toner image is fixed to the sheet on which the toner image is transferred by the fixing device 150. Sheet powder adhering to the surface of the transfer belt 105 and residual toner adhering to the surface of the photosensitive drum 102 are removed by the cleaning member 109.

  The sheet discharged from the fixing device 150 is transported through a straight transport path 160 as a transport path and is discharged to the sheet processing apparatus 2 by a discharge roller 180. Thereafter, the sheet discharged from the discharge roller 180 is received by the entrance roller 201 of the sheet processing apparatus 2 and is conveyed through the stack conveyance path 210. The sheets are discharged and stacked on the stack sheet stacking tray 230 as a stacking unit with the image forming surface facing up by the stack discharge roller 220.

  When the sheet is discharged to the sheet processing apparatus 2 with the image forming surface upside down, the sheet discharged from the fixing device 150 is conveyed to the switching member 175 on the downstream side of the post-fixing roller pair 151, and The reversing path 170a serving as a transport path on the upstream side of the reversing path 170 is transported. Thereafter, the sheet is continuously conveyed by the conveyance of the switching member 176, the rotation of the reverse roller 171, the conveyance of the switching member 176, and the rotation of the switchback roller 172. When the trailing edge reaches the vicinity of the reverse roller 171, the sheet is reversely fed by the reverse rotation of the reverse roller 171 and the switchback roller 172. Then, the sheet is conveyed to the reverse path 170 b on the downstream side of the reverse path 170 and is sent to the sheet processing apparatus 2 by the discharge roller 180. In this way, the sheet that has been switched back and conveyed through the reversing path 170 is turned upside down and sent to the sheet processing apparatus 2.

  When images are formed on both sides of the sheet, the sheet discharged from the fixing device 150 is conveyed to a switching member 175 serving as a refeed selection unit on the downstream side of the post-fixing roller pair 151, and the inversion path 170. Is conveyed along the reverse path 170a on the upstream side. Thereafter, the sheet is continuously conveyed by the rotation of the reverse roller 171, the conveyance of the switching member 176, and the rotation of the switchback roller 172. When the trailing edge of the sheet reaches close to the switchback roller 172, the switchback roller 172 stops rotating and temporarily stops conveyance. Then, when the switching member 176 is switched, the sheet is conveyed with its front and back reversed by the reverse rotation of the switchback roller 172 and the conveyance of the switching member 176. Thereafter, the sheet is conveyed through a double-sided conveyance path 174 as a re-feeding path by the normal rotation of the double-sided roller 173, and is sent to a sheet feeding conveyance path 149 as a conveyance path. The double-sided conveyance path 174 is configured so that the sheet can be reversed, and the sheet is reversed while conveying the sheet.

  The sheet is again subjected to skew correction by the registration roller pair 148 and then fed between the photosensitive drum 102 and the transfer unit 104. At this time, the sheet has a surface opposite to the surface to which the toner image has been transferred facing the photosensitive drum 102. Therefore, the toner image on the photosensitive drum 102 is transferred to the different surface. As a result, the toner image is transferred to both sides of the sheet, and is sent to the sheet processing apparatus 2 via the fixing device 150.

  When the stapler mode for binding sheets is input to the operation unit 140 by the user, the sheets fed to the sheet processing apparatus 2 are conveyed through the stapler conveyance path 240 and accumulated on the sheet processing tray 260 by the intermediate discharge roller 250. Is done. When a predetermined number of sheets are stacked on the sheet processing tray 260, the stapler 270 binds the sheet bundle. The sheet bundle is discharged onto the discharge tray 290 by the sheet bundle discharge roller 280 and stacked.

  In the image forming apparatus 1 described above, the preliminary discharge path 190 is used to discharge the sheet to the outside when it is set in advance or at the request of the user. The preliminary discharge path 190 is branched from the paper feed conveyance path 149 at a branch point X on the upstream side of the registration roller pair 148. At the branch point X, a switching member 195 is provided as a discharge selection unit that selectively switches between the sheet conveyance path 111 and the preliminary discharge path 190.

  When the switching member 195 is rotated to the lower position, the sheet is introduced from the paper feed conveyance path 149 to the preliminary discharge path 190 and is preliminarily stacked outside the image forming apparatus 1 by the preliminary discharge conveyance rollers 191 and 192. It is discharged to a preliminary discharge tray 130 as a means.

  In the sheet feeding conveyance path 149, the preliminary discharge path 190, the reversing path 170, and the double-side conveyance path 174 in the printer unit 110, a sheet detection that detects the sheet conveyance timing and determines whether or not there is a sheet feeding failure (jam). A sensor is provided. The sheet detection sensors are denoted by reference numerals S130, S146, S147, S147b, S148, S150, S151, S171, S172, S173, S180, S191, and S192 in FIG. Hereinafter, the reference numerals used to collectively refer to these sheet detection sensors are “S130 to S192”. Further, the longitudinal path roller pair 147, the registration roller pair 148, and the post-fixing roller pair 151 for conveying the sheet in the sheet feeding and conveying path 149 correspond to a rotating body pair for conveying the sheet and a conveying unit. Further, the photosensitive drum 102, the transfer unit 104, and the fixing roller pair 150a and 150b of the fixing device 150 can also convey the sheet, and thus correspond to the rotating member pair and the conveying unit.

  FIG. 3 is a control block diagram for controlling the image forming apparatus 1.

  A CPU (central processing unit) 199 that controls the image forming apparatus 1 is connected to each unit of the image forming apparatus 1 via a bus 200 such as a data bus. A ROM (Read Only Memory) 196 stores a program for sheet conveyance control which will be described later. A RAM (Random Access Memory) 193 temporarily stores data necessary for such control. The timer 194 measures time and is used at the time of calculating the sheet position. The input controller 197 inputs sheet detection signals from the sensors S130 to S192. The output controller 198 is connected to each of the transport roller motors (M130 to M192), the separation motors (M104, M153), and the plungers PL175 and PL195 that operate the switching members 175 and 195, respectively.

  Next, a sheet conveying operation will be described.

  6 to 7 are flowcharts for explaining the processing operation for switching the discharge path in the image forming apparatus of the present embodiment.

  The operation unit 140 (FIG. 1) includes button operation units such as a sample mode selection button 140a and an image formation mode selection button 140b, and a monitor unit that also serves as a touch panel. By touching the monitor unit, it is possible to switch to a setting screen such as an image forming number setting panel, a sample number specifying panel, a sheet size selecting panel, a single-sided double-sided image forming selecting panel, and a reduction / enlargement ratio adjusting panel. When the sample mode selection button 140a is pressed, the designated number of sheets are discharged from the outlet 190a of the preliminary discharge path 190 to the preliminary discharge tray 130 before the image of a large number of sheets is formed. It can be confirmed whether it is formed. When the image formation mode selection button 140b is selected, an image position adjustment mode for adjusting the position of the image formed on the sheet can be selected, and the setting can be made from the monitor unit. A sheet for confirming whether an image is formed as desired is taken as a sample sheet.

  Note that the outlet 190 a of the preliminary discharge path 190 is disposed closer to the preliminary discharge tray 130 than the stack sheet stacking tray 230. The case where the number of copies of the sample sheet SP is designated as 1 will be described below.

  When the sample mode selection button 140a and the image formation mode selection button 140b are selected, information on the discharge path switching instruction is transmitted to the CPU 199 via the input controller 197 (S1 in FIG. 6). When the CPU 199 obtains the conveyance switching information, the CPU 199 starts the discharge path switching process.

  When the discharge path switching process is started, the CPU 199 displays on the operation unit 140 a message prompting the user to jam the sheet on the sheet conveyance path of the image forming apparatus (S3).

  The CPU 199 detects whether a sheet jammed in the straight conveyance path 160 has been removed by the user and all sheets on the sheet conveyance path of the image forming apparatus have been discharged by the sheet detection sensors S130 to S192, and determines the presence or absence of the sheet. (S2).

  If there is no sheet in the sheet feeding conveyance path 149, the image forming unit 144, the fixing device 150, the reversing path 170a, the duplex conveyance path 174, the sheet feeding conveyance path 149, and the preliminary discharge path 190 (NO in S2), the CPU PL199 To control. Plunger PL175 rotates switching member 175 upward (S4). When the switching member 175 is rotated upward, the sheet after image formation is not sent to the sheet processing apparatus 2 but is prepared to be conveyed to the reversing path 170a. The CPU 199 controls the plunger PL195, rotates the switching member 195 upward (S5), and prepares the sheet fed from the cassette 145 to be conveyed to the image forming unit 144 and the fixing device 150.

  The image forming unit 144 includes the photosensitive drum 102, the developing device 103, the transfer unit 104, and the like.

  From the junction Y between the duplex conveyance path 174 and the sheet feed conveyance path 149, the sheet passes through the sheet feed conveyance path 149, the image forming unit 144, the fixing device 150, the reverse path 170 a, and the duplex conveyance path 174 and returns to the junction Y. The number of sheets that can be simultaneously conveyed to the circulation conveyance path 177 that is the path is N. This N varies depending on the sheet size (length), but is the maximum number of sheets stored in advance in the ROM 196 for each sheet size.

  The CPU 199 checks the number m counted by the document feeder 120A and the sheet size stored in the RAM 193 or input from the operation unit 140. If the sheet size is not stored, the CPU 199 displays a message prompting the user to input the sheet size to the operation unit 140 (S6). These m sheets are discharged from the outlet 190a of the preliminary discharge path 190 to the preliminary discharge tray 130 before the image formation of a large number of sheets, and a sample sheet SP for confirming whether an image is formed on the sheet as desired. The number of sheets (number of originals) forming one part of the above.

  The CPU 199 checks m and N from the ROM and RAM (S5). If N> m (YES in S7), the CPU 199 sets m sheets, feeds the paper feed unit 146 from the cassette 145, and sets the vertical pass roller pair 147 to the motor M145. The sheet is fed by M146 (FIG. 8, S81). If N ≦ m (NO in S7), the CPU 199 feeds N sheets from the cassette 145, the paper feed unit 146, and the vertical path roller pair 147 by the motors M145 and M146 (S71).

  In the case of (N ≦ m) (NO in S7), the processes S7, S71 to S76, S77 to S93, and S6 are repeated m / N (the decimal point is rounded up) times. In this case, the number of sheets to be handled last is not necessarily N, and may be less than N.

  First, the first round will be described.

  Now, it is assumed that (N ≦ m) (NO in S7). At this time, at the branch point X between the preliminary discharge path 190 and the sheet conveyance path 111, the switching member 195 is rotated upward, so that the sheet is fed to the image forming unit 144.

  The CPU 199 controls the image forming unit 144 and the fixing device 150 to form an image on the sheet (S72).

  The CPU 199 drives the image forming unit 144, the fixing device 150, the post-fixing roller pair 151, the reversing roller 171, the switchback roller 172, and the double-sided roller 173 toward the sheet feeding conveyance path 149. (S72).

  Further, the CPU 199 detects the number of sheets that have been fed from the cassette 145 at the time when the feeding of the sheet is started, based on the sheet detection of the sensor S147b provided in the sheet feeding path 149 and the count of the feeding counter 189. The data are sequentially stored in the RAM 193. Then, when the count reaches N, the CPU 199 stops the sheet feeding by the sheet feeding unit 146 as a feeding unit (S73, S74). However, the CPU 199 continues the conveyance of the sheet after the image formation being conveyed to the junction Y, and conveys the sheet after the image formation to the paper feed conveyance path 149 (S75). However, the sheet after image formation that is conveyed to the merge point Y is timed so that the trailing edge of the Nth sheet passes through the merge point Y and then enters the sheet feed path 149. ing. Therefore, the sheet after the image formation does not enter the paper feed conveyance path 149 before the Nth sheet and overlap with the Nth sheet.

  Here, the CPU 199 confirms whether to form an image only on one side of the sheet or to form an image on both sides of the sheet from the RAM 193 in which information previously input by the user from the operation unit 140 is stored (S76). .

  If the CPU 199 is performing single-sided image formation (YES in S76), the CPU 199 proceeds to processing S77. The CPU determines from the sheet moving speed, the time when the trailing edge of the N-th image-unformed sheet fed from the cassette 145 has passed the sensor S147b, the length information in the sheet conveyance direction, and the timer 194. , It is determined that the Nth sheet has passed through the switching member 195 (S77). In this case, the sheet detection sensor S148 may confirm that the Nth sheet has passed. The sheet moving speed is calculated from the outer diameter and rotation speed of the vertical path roller pair 147. The length information in the sheet conveyance direction is previously input by the user from the operation unit 140 and stored in the RAM 193.

  At the same time, the CPU switches the sheet after image formation to the switching member 195 from the sheet moving speed, the time when the leading edge of the (N + 1) th sheet has passed the sensor S147b, the length information in the sheet conveyance direction, and the timer 194. It is determined that it exists on the upstream side (S77).

  Note that the (N + 1) th sheet has not been fed from the cassette 145 after the feeding of the sheet from the cassette reaches the Nth sheet in process S74. Absent. The (N + 1) th sheet is a sheet after image formation that has entered the sheet feeding conveyance path 149 from the duplex conveyance path 174 at the junction Y. That is, the (N + 1) th sheet is the first sheet that has been formed on one side and has made a round of the printer unit 110, and since the CPU continues counting, the first sheet that has made a round of the inside of the image forming apparatus. The sheet is counted as the (N + 1) th sheet.

  When the CPU confirms that the Nth sheet fed from the cassette has passed through the switching member 195 and the (N + 1) th sheet after image formation on one side is upstream of the switching member (YES in S77), The plunger PL195 is controlled to rotate the switching member downward (S90). In this case, the detection that the sheet has passed the switching member 195 may be performed by the sheet detection sensor S148.

  The switching member rotated downward conveys the (N + 1) sheet having an image formed on one side thereof to the preliminary discharge path 190. The CPU 199 drives the preliminary discharge conveyance roller 191 to discharge the sheet having an image formed on one side thereof to the preliminary discharge tray 130 that is open to the outside of the image forming apparatus 1 (S91).

  When the CPU 199 obtains information that the trailing edge of the N-th sheet fed from the cassette 145 has passed the sensor S192 among the sheets on which an image is formed on one side (S91, S92), the N on which the image is formed on one side. It is determined that the sheet has been discharged to the preliminary discharge tray 130. This discharged sheet is the sample sheet SP. Then, the CPU 199 rewrites the value of m stored in the RAM 193 to (m−N) (S93), and starts paper feeding again. Thereafter, the CPU 199 repeats the process until m = 0 (S6).

  Therefore, one copy (m sheets) of the sample sheet SP is discharged and stacked on the preliminary discharge tray 130.

  In the above description, if N> m in process S7 (YES in S7), the CPU 199 performs processes S81 to S86. If it is single-sided printing in process S86, the CPU 199 performs processes S87 to S102. In this case, the process from the process S81 to the process S102 is the same as the process S71 to the process S92 described above, and only N is changed to m in the process S71 to the process S92. Therefore, the description of the process is omitted. To do.

  Next, a case where information for forming images on both sides of the sheet is obtained from the storage device in processing S76 (NO in S76) will be described. However, the number of sheets to be fed is N.

  The CPU 199 sequentially forms images on both sides of the sheet (S78). At this time, the CPU calculates (2 × N) sheets from the sheet moving speed, the time when the trailing edge of the (2 × N) th sheet has passed the sensor S147b, the sheet conveyance direction length information, and the timer 194. It is determined that the image-formed sheet has passed through the switching member 195 on one side of the eye (S79).

  Note that the (2 × N) th sheet is fed Nth from the cassette 145, detected by the sensor S147b, and formed on one side, and then travels around the circulation conveyance path 177 and is fed from the junction Y. The sheet enters the paper conveyance path 149 and is detected again by the sensor S147b. That is, the (2 × N) th sheet is a sheet detected twice by the sensor S147b. The (2 × N) th sheet is a sheet that is also detected twice by the sheet detection sensor S148. Further, the sheet moving speed is calculated from the outer diameter and rotation speed of the vertical pass roller pair 147. The time when the trailing edge of the (2 × N) th sheet has passed the sensor S147b is the time after the feeding from the cassette 145 is started. The length information in the sheet conveyance direction is stored in advance in the RAM 193 input by the user from the operation unit 140.

  At the same time, the CPU 199 switches the sheet after image formation on both sides from the sheet moving speed, the time when the leading edge of the (2N + 1) th sheet passes the sensor S147b, the length information in the sheet conveyance direction, and the timer 194. It is determined that it exists on the upstream side of the member 195.

  Note that the (2N + 1) th sheet is the (2 × N) th next sheet. That is, the (2N + 1) -th sheet is the leading sheet that has been formed on both sides of the circulation conveyance path 177 and has been continuously counted. The first sheet is counted as the (2N + 1) th sheet.

  The sheet moving speed is calculated from the outer diameter and rotation speed of the vertical pass roller pair 147. The time when the leading edge of the (2N + 1) th sheet has passed through the sensor S147b is the time after the feeding is started from the cassette 145. The length information in the sheet conveyance direction is stored in advance in the RAM 193 input by the user from the operation unit 140.

  When the CPU confirms that the (2 × N) th sheet passes through the switching member 195 and the (2N + 1) th sheet passes through the sensor S147b and is upstream of the switching member, the CPU controls the plunger PL195, The switching member 195 is turned downward (S79, S90).

  The switching member 195 rotated downward conveys the (2N + 1) sheets having images formed on both sides thereof to the preliminary discharge path 190. The CPU 199 drives the preliminary discharge conveyance roller 191 to discharge the sheet on which the image is formed on both sides to the preliminary discharge tray 130 opened to the outside of the image forming apparatus 1 (S91).

  When the CPU obtains information that the trailing edge of the 2N sheet fed Nth from the cassette 145 passes through the sensor S192 among the sheets on which images are formed on both sides (S91, S92), the image is formed on both sides. It is determined that N sheets are discharged to the preliminary discharge tray 130. Then, the CPU 199 rewrites the value of m stored in the RAM 193 to (m−N) (S93), and starts paper feeding again. Thereafter, the CPU 199 repeats the process until m = 0 (S6).

  In the above description, if N> m in process S7 (YES in S7), the CPU 199 performs processes S81 to S86, and if the duplex printing is performed in process S86, the processes S88 to S102 are performed. In this case, the processing from the processing S81 to the processing S88 to the processing S102 is the same as the processing from the processing S71 to the processing S78 to the processing S92, and only N in the processing S71 to S92 is changed to m. The description of the processing will be omitted.

  The image forming apparatus described above is configured to feed a sheet from the cassette 145. However, when the sheet is fed from the external paper feeding device 3, the same sample sheet discharging operation can be performed.

  If the counting sensor for detecting sheets and the cassette 145 are too far apart to count the sheets, when the counting sensor detects the Nth sheet, the Nth sheet and the cassette 145 are detected. The distance between the sheet and the sheet from which feeding is stopped is increased. For this reason, the sheet conveyance interval is widened, and the maximum number of sheets stored in the circulation conveyance path 177 is reduced. Therefore, the sensor for counting is preferably closer to the cassette 145. Accordingly, the counting sensor in the above embodiment is the sheet detection sensor S147b provided between the junction point Y and the branch point X, but the sheet provided between the cassette 145 and the junction point Y. The detection sensors S130 and S147 may be counting sensors.

  Although the preliminary discharge tray 130 is disposed on the external paper feeding device 3, it may be attached to the right side surface of the printer unit 110 in FIG. 1, and the installation location is not limited. That is, it is only necessary that the preliminary discharge tray 130 be disposed near the operation unit 140 and the outlet 190 a of the preliminary discharge path 190.

  The image forming apparatus described above forms images on both sides of the sheet, but may form images only on one side. In this case, the double-sided conveyance path 174 does not need to be able to reverse the sheet.

  Further, the image forming apparatus automatically restarts the image forming operation when there is no change in information input to the operation panel even after the user confirms the image on the sample sheet, and the sheet is The sheets may be automatically discharged to the stack sheet stacking tray 230.

  The preliminary discharge means described in claim 1 includes a reverse path 170a, a double-sided conveyance path 174, a paper feed conveyance path 149, a sheet conveyance path 111, a switching member 195, a preliminary discharge path 190, and the like. The selection means is a switching member 175.

  In the above description, the number of sheets constituting the “number” of “number of image forming copies” is not limited to a plurality of sheets but may be one. That is, “one part” in the present invention includes not only a plurality of sheets but also one sheet.

  In the image forming apparatus described above, when there are a plurality of image forming copies input to the operation unit 140, the first part of the image formed is discharged as a sample sheet for image formation confirmation near the operation panel. Can be done.

  As shown in FIGS. 4 and 5, in the image forming apparatus according to the present embodiment, when the user checks the image of the sample sheet, the image is discharged from the outlet 190 a of the preliminary discharge path 190 to the preliminary discharge tray 130 near the operation unit 140. It comes to discharge. For this reason, it is not necessary to go to the stack sheet stacking tray 230 at a position away from the operation unit 140, and the sample sheet image can be confirmed by the operation unit 140. Therefore, the image forming apparatus can check the sample sheet on the preliminary discharge tray 130 without the user leaving the operation unit 140, and can efficiently perform the image checking operation without unnecessary movement.

  In addition, when the user wants to correct an image as a result of confirming the image on the image formation confirmation sheet, the image forming apparatus has an operation unit 140 beside the image formation confirmation sheet. Well done.

  Therefore, the image forming apparatus can improve operability.

FIG. 2 is a schematic cross-sectional view along the sheet conveying direction of the image forming apparatus according to the embodiment of the present invention. FIG. 2 is a diagram illustrating a sensor and a motor in the image forming apparatus of FIG. 1. FIG. 2 is a control block diagram of the printer unit in FIG. 1. FIG. 2 is a perspective view of the image forming apparatus of FIG. 1 as viewed obliquely from above. FIG. 2 is an external plan view of the image forming apparatus in FIG. 1. 3 is a flowchart for explaining a preliminary discharge switching operation in the image forming apparatus of FIG. 1. It is a flowchart following FIG. It is a flowchart following FIG.

Explanation of symbols

P sheet X Junction point between paper feed conveyance path and preliminary discharge path Y Junction point between double-sided conveyance path and paper feed conveyance path SP Sample sheet S148 Sheet detection sensor 1 Image forming apparatus 2 Sheet processing apparatus 130 Preliminary discharge tray (preliminary stacking) means)
140 Operation unit 144 Image forming unit 145 Cassette 146 Paper feed unit 149 Paper feed transport path (transport path)
174 Double-sided conveyance path (refeed path)
175 switching member (selection means, refeed selection means)
177 Circulation conveyance path 189 Feed counter 190 Preliminary discharge path 190a Preliminary discharge path outlet 195 Switching member (discharge selection means)
199 CPU (control means)
230 Stacked sheet stacking tray (stacking means)
170a Inversion path (preliminary discharge means)
174 Double-sided conveyance path (preliminary discharge means)
149 Paper feed path (preliminary discharge means)
111 Sheet conveyance path (preliminary discharge means)
195 Switching member (preliminary discharge means)
190 Preliminary discharge path (Preliminary discharge means)

Claims (5)

An image forming unit for forming an image on a sheet;
A stacking unit that stacks sheets on which images are formed by the image forming unit;
A preliminary discharge unit that conveys a sheet on which an image is formed by the image forming unit to the outside from between the image forming unit and the stacking unit;
Selection means for selecting the loading means and the preliminary discharge means;
An operation unit for inputting the number of image forming copies;
When the sample mode for discharging and confirming the first predetermined number of sheets formed with images among the plurality of image forming copies input to the operation unit is selected, the sheet is conveyed to the preliminary discharge unit in order to convey the sheet to the preliminary discharge unit Control means for causing the selection means to select the preliminary discharge means,
The outlet of the preliminary discharge means is disposed at a position closer to the operation unit than the loading means.
An image forming apparatus. An image forming unit that forms an image on a sheet that has been conveyed through a conveyance path that conveys the sheet;
A stacking unit that stacks sheets on which images are formed by the image forming unit;
A refeed path for transporting an image-formed sheet from between the image forming unit and the stacking unit to the transport path;
Refeed selection means for selecting the loading means and the refeed path;
A preliminary discharge path that is branched from the conveyance path between the confluence of the refeed path and the conveyance path and the image forming unit and conveys the sheet to the outside;
A discharge selecting means for selecting the image forming unit and the preliminary discharge path;
An operation unit for inputting the number of image forming copies;
When the sample mode for discharging and confirming the first predetermined number of sheets formed with images among the plurality of image forming copies input to the operation unit is selected, the sheet is transported to the preliminary discharge path, Control means for causing the refeed selection means to select the refeed path and causing the discharge selection means to select the preliminary discharge path,
The outlet of the preliminary discharge path is disposed at a position closer to the operation unit than the loading means.
An image forming apparatus. Provided with preliminary stacking means for stacking sheets discharged from the outlet;
The image forming apparatus according to claim 1, wherein the image forming apparatus is an image forming apparatus. The control unit can temporarily stop the operation of the image forming unit after the image forming unit has formed an image on the predetermined number of sheets.
The image forming apparatus according to claim 1, wherein the image forming apparatus is an image forming apparatus. The refeeding path is capable of reversing the sheet upside down.
The image forming apparatus according to claim 2.

Images