JP2015028514A - Image forming apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image forming apparatus configured to improve throughput even if sheet feeding operation is started after the start of forming a toner image.SOLUTION: An image forming apparatus includes: a sheet feeding section 20 which feeds a sheet; an image forming section 10 comprising image forming units 11a-11d for forming toner images on photoreceptor drums 12a-12d, an intermediate transfer belt 13 for transferring the toner images formed on the photoreceptor drums 12a-12d to the sheet, and a secondary transfer section 30; and a timer 150 which detects sheet moving time between two points before the secondary transfer section 30; and a control section 110 which makes a toner-image forming interval for the image forming units 11a-11d to form toner images on the photoreceptor drums 12a-12d, shorter than a preset initial interval, on the basis of the detected moving time, when images are formed on the sheets successively and the moving time detected by the timer 150 is shorter than a preset time.

Description

  The present invention relates to an image forming apparatus such as a copying machine, a printer, and a facsimile.

  In general, the image forming apparatus has individual characteristics (part tolerance and variation during assembly), usage environment (temperature and humidity), wear of the conveyance roller and conveyance guide due to durability, and type and state of the sheet (temperature, moisture absorption amount, The sheet conveyance time varies depending on the amount of charge).

  For example, when the individual characteristics are factors, the transmission time of the drive train that transmits the drive to the conveyance rollers, the distance between the conveyance rollers, the physical position of the sensor used for conveyance control, etc. vary, thereby reducing the sheet conveyance time. Variation occurs. In addition, when the environment in which the sheet is used and the type and state of the sheet are factors, the sheet conveyance time varies because the friction coefficients of the sheets, the sheet and the conveyance guide, and the sheet and the conveyance roller change. In addition, when the wear of the conveyance roller due to durability is a factor, when the diameter of the conveyance roller is reduced due to wear, the distance traveled by one rotation of the conveyance roller is shortened, and the friction coefficient of the roller surface is changed. Variations in transport time occur.

  In response to this, there has been proposed an image forming apparatus that automatically detects a variation in sheet conveyance speed and controls the sheet to be fed at an optimum feeding interval that provides the fastest throughput based on the detection result. (See Patent Document 1).

JP 2007-79011 A

  Here, since the image forming apparatus described in Patent Document 1 is configured to form a toner image on the image carrier based on the position of the sheet after the sheet feeding operation is started, the sheet is fed at an optimum feeding interval. If it is sent, the toner image can be transferred to the sheet with the fastest throughput. On the other hand, in the case of an image forming apparatus that starts a sheet feeding operation after starting a toner image forming operation, conventionally, a toner image is formed on an image carrier at a constant interval. Even if it was fed, the throughput could not be improved.

  Therefore, an object of the present invention is to provide an image forming apparatus capable of improving throughput even when a sheet feeding operation is started after a toner image forming operation is started.

  In the image forming apparatus, a sheet feeding unit that feeds a sheet, a toner image forming unit that forms a toner image on an image carrier, and a toner image formed on the image carrier are transferred to the sheet. An image forming unit having a toner image transfer unit, a moving time detection unit capable of detecting a moving time of a sheet between two points to the toner image transfer unit, and when forming an image continuously on a sheet, When the movement time detected by the movement time detection means is shorter than a preset time, the toner image forming interval at which the toner image forming means forms a toner image on the image carrier is set to the detected movement time. And a control means for making the interval shorter than a preset initial interval.

  According to the present invention, in an image forming apparatus that starts a sheet feeding operation after starting a toner image forming operation by setting a toner image forming interval based on at least a sheet moving time between two points. Also, the throughput can be improved.

1 is a cross-sectional view schematically showing a printer according to an embodiment of the present invention. It is a block diagram of a control unit of the printer according to the present embodiment. It is a figure for demonstrating the position between two points at the time of setting the image writing space | interval in single-sided printing mode. It is a figure for demonstrating the setting of an image writing space | interval. It is a figure for demonstrating the setting of the image writing space | interval which concerns on this embodiment. It is a figure which shows the switching timing of the image writing space | interval which concerns on this embodiment. It is a flowchart which shows the switching timing of the image writing space | interval which concerns on this embodiment. It is a figure for demonstrating the position between two points at the time of setting the image writing space | interval in duplex printing mode.

  Hereinafter, an image forming apparatus according to an embodiment of the present invention will be described with reference to FIGS. 1 to 8. An image forming apparatus according to an embodiment of the present invention is an image forming apparatus such as a copying machine, a printer, a facsimile machine, or a complex machine thereof. In the following embodiments, an electrophotographic full color laser printer (hereinafter referred to as “printer”) will be described as an image forming apparatus.

  A schematic configuration of the printer 1 according to the present embodiment will be described with reference to FIGS. 1 and 2. As shown in FIG. 1, the printer 1 includes an image forming unit (image forming unit) 10 provided inside a printer main body 100 and a sheet feeding unit (sheet feeding unit) provided below the image forming unit 10. ) 20 and a control unit (control means) 110 for controlling them. The printer 1 also includes a temperature sensor 120 that can detect the ambient atmosphere temperature inside the printer 1, a humidity sensor 130 that can detect the ambient atmosphere humidity inside the printer 1, and a sheet that can determine the type of sheet to be fed. Discriminating sensor (sheet discriminating means) 140. Further, the printer 1 includes a timer (movement time detecting means) 150 capable of measuring the movement time (conveyance time) of the sheet S between two points.

  The image forming unit 10 includes image forming units (toner image forming units) 11a to 11d that form toner images of yellow, magenta, cyan, and black, and an intermediate transfer belt (toner image transfer unit) that primarily transfers the toner images. 13. Further, the image forming unit 10 includes a secondary transfer unit (toner image transfer unit) 30 for secondary transfer of the toner image and a fixing unit 40 for fixing the toner image. The sheet feeding unit 20 includes a feeding cassette 21 that stores sheets, a pickup roller 22 that picks up the sheet S from the feeding cassette 21, a feed roller 23 and a retard roller 24 that separate and feed the sheets S one by one. It is equipped with. As shown in FIG. 2, the control unit 110 includes a CPU 111 that drives and controls the image forming unit 10 and the like, and a memory 112 that stores various programs and a movement time T of a sheet S described later.

  The sheet determination sensor 140 determines the sheet type based on the rigidity of the sheet S. The rigidity of the sheet S is determined based on, for example, the basis weight or thickness of the sheet. In the present embodiment, the sheet determination sensor 140 is configured to determine the type of the sheet based on the rigidity of the sheet S. However, the sheet type is determined based on other characteristics such as a friction coefficient of the surface of the sheet. You may comprise so that it may discriminate | determine.

  Next, the image forming operation (image forming control by the control unit 110) of the printer 1 configured as described above will be described with the control unit 110 as a main component. The printer 1 forms a single-sided printing mode in which an image is formed only on one side (first side) of a sheet S such as recording paper as a recording medium, and forms an image on both sides (first side and second side) of the sheet S. The duplex printing mode can be set. Hereinafter, a case where the single-sided printing mode is selected and a case where the double-sided printing mode is selected will be described.

  First, a case where the single-sided printing mode is selected will be described. Upon receiving the image information signal of the first surface, the controller 110 charges the photosensitive drums (image carriers) 12a to 12d provided in the image forming units 11a to 11d, and based on the received image information signal, A toner image of each color is formed on the photosensitive drums 12a to 12d. At this time, the control unit 110 transmits an image writing signal. Note that “image writing” here refers to the start of toner image formation on the photosensitive drum. Next, the control unit 110 sequentially superimposes and transfers the toner images of the respective colors formed on the photosensitive drums 12a to 12d onto the intermediate transfer belt 13 to form a full color toner image on the intermediate transfer belt 13 (primary transfer). Let

  Further, the control unit 110 causes the sheet feeding unit 20 to feed the sheet S after a predetermined time has elapsed since the image writing signal is transmitted. Specifically, the control unit 110 drives the pickup roller 22 to pick up the sheet S stored in the feeding cassette 21 and drives the feed roller 23 and the retard roller 24 to intermediately convey the sheet S one by one. The roller pair 25 is fed.

  Next, the control unit 110 drives the intermediate conveyance roller pair 25 to convey the sheet S to the registration roller pair 26. A top sensor 27 that detects the arrival timing of the leading edge of the sheet S is provided downstream of the registration roller pair 26 in the sheet conveyance direction. The control unit 110 drives the registration roller pair 26 at a predetermined timing based on the detection result of the top sensor 27 to convey the sheet S to the secondary transfer unit 30. Then, when the sheet S passes through the secondary transfer unit 30, the secondary transfer unit 30 is controlled to transfer the full-color toner image on the intermediate transfer belt 13 onto the first surface of the sheet S.

  Next, the control unit 110 controls the fixing unit 40 to fix the toner image with heat and pressure, and the switching member 60 provided downstream of the fixing unit 40 is moved to the first position (60a shown in FIG. 1). Switch. When the sheet S is guided to the discharge roller pair 70 by the switching member 60 switched to the first position, the control unit 110 controls the discharge roller pair 70 to discharge the sheet S to the sheet discharge tray 101. This completes the single-sided printing mode.

  Next, the case where the duplex printing mode is selected will be described. When the duplex printing mode is selected, when the toner image on the first surface is fixed by the fixing unit 40, the control unit 110 switches the switching member 60 to the second position (60b shown in FIG. 1), and the sheet S Is guided to the pair of reverse rollers 61. Specifically, the control unit 110 switches the switching member 60 to the second position after a predetermined time has elapsed after the top sensor 27 detects the leading edge of the sheet S, rotates the reverse roller pair 61 forward, and temporarily A part of the sheet S is led out onto the sheet discharge tray 101.

  Next, when the trailing edge of the sheet S is detected by the reverse sensor 62 and the time required for the trailing edge of the sheet S to reach the switching member 60 has elapsed, the control unit 110 stops the rotation of the pair of reverse rollers 61. Then, the conveyance of the sheet S is stopped while the sheet S is nipped. At this time, the controller 110 switches the switching member 60 from the second position 60b to the first position 60a.

  Next, the control unit 110 rotates the reverse roller pair 61 in the reverse direction to convey the sheet S in the reverse direction (switchback conveyance) and convey it to the double-sided conveyance path 63. When the sheet S is conveyed to the duplex conveying path 63, the control unit 110 causes the duplex sheet conveying roller pair 64 to convey the sheet S, and once the leading edge of the sheet S is nipped by the U-turn conveying roller pair 65, the controller 110 once conveys the sheet S. Stop. The control unit 110 then re-drives the U-turn conveyance roller pair 65 to re-convey to the registration roller pair 26 after a lapse of a predetermined time after transmitting the image writing signal. When the sheet S is conveyed again to the registration roller pair 26, the control unit 110 forms an image on the second surface of the sheet S by the same processing as in the case of single-sided printing. As a result, the duplex printing mode ends.

  Next, a method for setting an image writing timing interval (hereinafter referred to as “image writing interval”) during continuous printing in order to improve the throughput of the printer 1 configured as described above (achieve the fastest throughput). This will be described with reference to FIGS.

  First, the constraint condition that determines the image writing interval is the movement time T from the start of the sheet S feeding operation (see FIG. 3A) to the leading edge detection by the top sensor 27 (see FIG. 3B). A conventional method for setting the image writing interval will be described with reference to FIG.

  When the moving time T is earlier than the predetermined time, the sheet S reaches the secondary transfer unit 30 earlier, and the full-color toner image is not transported in time by the intermediate transfer belt 13, resulting in a printing error. Similarly, when the moving time T is later than the predetermined time, the arrival of the sheet S to the secondary transfer unit 30 is delayed, which results in a printing error. Therefore, in the past, in consideration of the minimum condition of the variation factor of the moving time T, the image writing interval at the time of continuous printing is determined for all printers regardless of the ability of each printer. Specifically, an image writing interval having a time margin (time margin) is set for the printing error area so that the sheet moving time does not become faster or slower than a predetermined time.

  For example, in FIG. 4, the horizontal axis represents time, the vertical axis represents frequency, and the solid line represents the distribution of travel time T in consideration of the minimum condition of variation factors. The nth, n + 1th, and so on are pasted. It is attached. Also, t0 (n) is the feeding operation start time, t1 (n) is the time from t0 (n) to the nth early-arrival printing error area, and t2 (n) is t0 (n) to the variation factor. The minimum time of the distribution of the movement time T in consideration of the minimum condition is shown. t3 (n) is t0 (n) to the maximum time of the distribution of the movement time T in consideration of the minimum condition of variation factors, and t4 (n) is movement from t0 (n) to the nth delay side printing error area. Time, T (NG), indicates the time of the printing error area. T (MN) indicates the distribution width of the travel time T in consideration of the minimum condition of the variation factor. Note that tm (n) = tm (n + 1) and m = 1, 2, 3, and 4.

  If t4 (n) -t3 (n)> 0 and t2 (n + 1) -t1 (n + 1)> 0, then the minimum sheet interval A (seconds) is A = {t4 (n) -t3 (n)} + T (NG) + {t2 (n + 1) -t1 (n + 1)}. Then, the image writing interval t (seconds) is t = T (MN) + A, and the throughput SP is SP (sheets / second) = 60 / t. Note that t4 (n) −t3 (n) indicates a time margin from the maximum time of the distribution of the movement time T in consideration of the minimum condition of the variation factor to the printing error area on the delay side. In addition, t2 (n + 1) −t1 (n + 1) indicates a time margin from the minimum time of the distribution of the movement time T in consideration of the minimum condition of the variation factor to the early arrival side printing error area.

  However, each printer actually used by the user has a variation in the distribution width T ′ (MN) (n) of the movement time T ′ from the start of the feeding operation to the detection of the leading edge of the top sensor sheet in the case of continuous printing. It becomes smaller than the distribution width T (MN) of the movement time T in consideration of the minimum condition. This is because there is no change in the component tolerances and assembly variations of individual printers, the environment (temperature and humidity) in which the printer is used does not change rapidly, and the transport rollers and transport guides rapidly This is because it will not wear out.

  Therefore, when the image writing interval t is set as in the prior art, the time margin to the printing error area, that is, the image writing interval becomes larger than necessary, so that there is a surplus printer.

  Next, FIG. 4 shows an image writing interval setting method according to this embodiment when the constraint condition that determines the image writing interval is the movement time from the start of the sheet S feeding operation to the leading edge detection by the top sensor 27. In addition, a description will be given with reference to FIG. In this embodiment, by changing the image writing interval (toner image forming interval) during continuous printing from t (seconds) to t ′ (seconds), control is performed with the fastest throughput that matches the capabilities of individual printers. . This will be specifically described below.

  When the user sets the number of continuous prints (n) and printing is started, the movement time T ′ of the sheet S for the latest P (n> P) (predetermined number) is stored in the memory 112. The distribution of the movement time T ′ of the stored P sheets S is indicated by broken lines in FIGS. 4 and 5. As shown in FIG. 4, the distribution width T ′ (MN) (n) of the movement time T ′ is smaller than the distribution width T (MN) of the movement time T considering the minimum condition.

  Here, as shown in FIG. 5, t′0 (n) is the feeding start time, t′1 (n) is the time from t′0 (n) to the nth early-arrival printing mistake area, t '2 (n) represents the minimum time of the distribution of the movement time T' considering the minimum condition of t'0 (n) to the variation factor. t′3 (n) is t′0 (n) to the maximum time of the distribution of the movement time T ′ considering the minimum condition of variation factors, and t′4 (n) is t′0 (n) to nth. The movement time to the printing error area on the delay side, T (NG), indicates the printing error area time. T ′ (MN) (n) represents the distribution width of the movement time T ′, and t1 (n) = t′1 (n).

  {T′4 (n) −t′3 (n)} = {t4 (n) −t3 (n)}, {t′2 (n) −t′1 (n)} = {t2 (n) − When t1 (n)} is set, the minimum sheet interval (seconds) is A (seconds), which is the same as the case where the minimum condition of the variation factor of the movement time T is considered. The image writing interval t ′ is t ′ = T ′ (MN) (n) + A. The image writing interval t ′ is shorter by {T (MN) −T ′ (MN) (n)} (seconds) than the image writing interval t in consideration of the minimum condition of variation factors. Therefore, the throughput SP ′ is SP ′ (sheets / second) = 60 / t ′ = 60 / (t− {T (MN) −T ′ (MN) (n)}), and the minimum condition of the variation factor is considered. In this case, the throughput SP can be made faster.

  In addition, the time margin for the printing error area is equal to or greater than that when the minimum condition of the variation factor is considered. For this reason, the probability of occurrence of a printing error due to the early arrival or delay of the sheet S from the start of the feeding operation to the detection of the leading edge of the sheet S is equal to or less than the case where the minimum condition of the variation factor is considered.

  Next, the switching timing of the image writing interval set as described above will be described with reference to FIGS. As shown in FIGS. 6 and 7, when the user sets the continuous print number (n) and the printing is started, the minimum condition of the variation factor of the movement time T is set up to the predetermined number (Pth). Printing is performed at a throughput SP (sheets / second) = 60 / t in consideration (step S1). In the printer 1, the throughput SP (sheets / second) considering the minimum condition of the variation factor of the moving time T is set as an initial setting (an initial interval set in advance of the image forming interval).

  Next, when the continuous printing up to the Pth sheet is completed, the throughput is switched from the P + 1th sheet to the throughput SP ′ = 60 / t ′ (P + 1) (steps S2 and S4). For the (P + 1) th and subsequent sheets, the image writing interval t ′ is set according to the detection result of the latest movement time T ′, and the image writing signal is transmitted at the image writing interval t ′. That is, the remaining continuous printing is executed at the image writing interval t ′.

  For example, when the movement time T ′ of the (P + 1) th sheet does not exceed the distribution range of the latest movement time T ′, the distribution width T ′ (MN) (P + 2) is larger than the distribution width T ′ (MN) (P + 1). Shorter. Therefore, the image writing interval t ′ (P + 2) is shorter than the image writing interval t ′ (P + 1). On the other hand, for example, when the movement time T ′ of the (P + 1) th sheet exceeds the distribution range of the latest movement time T ′, the distribution width T ′ (MN) (P + 2) is the distribution width T ′ (MN) ( Longer than P + 1). In this case, the image writing interval t ′ (P + 2) may be longer than the image writing interval t ′ (P + 1). In this way, the throughput SP ′ can be adjusted based on the new travel time T ′ at all times, and the optimum throughput SP ′ can be set for variations in the travel time T ′.

  Next, when the type of the sheet S determined by the sheet determination sensor 140 changes during execution of continuous printing at the throughput SP ′, the image writing interval is returned to the initial setting (step S5). That is, the throughput SP ′ is returned to the throughput SP. Similarly, when the change amount of the ambient atmosphere temperature detected by the temperature sensor 120 within the predetermined time or the change amount of the ambient atmosphere humidity detected by the humidity sensor 130 exceeds the predetermined change amount, the image writing interval is initially set. (Step S5). That is, the throughput SP ′ is returned to the throughput SP.

  This is because when the ambient ambient temperature and ambient ambient humidity of the printer 1 change by a predetermined amount or more within a predetermined time (for example, a short time), the sheet rigidity changes, so that the sheet conveyance path changes. When the conveyance path of the sheet changes, the friction coefficient with the conveyance guide and the conveyance roller changes, so that the distribution of the movement time changes. If the distribution of the movement time changes suddenly, there is a possibility that the movement time T ′ may enter the printing error area at the throughput SP ′ of the image writing interval t ′ determined by the movement time for the latest P sheets. Bigger than that. Therefore, it is possible to reduce printing mistakes by returning to the initial setting.

  After returning to the throughput SP, when continuous printing up to the Pth sheet is finished, the throughput is switched from the P + 1th sheet to the throughput SP ′ = 60 / t ′ (P + 1) in the same manner as described above, and the above-described process is performed until the print job is completed. Is repeated (steps S2 to S6).

  As described above, the printer 1 according to the present embodiment detects the moving time of the sheet S between two points from the start of feeding to the leading edge detection by the top sensor 27, and the image writing interval based on the detected moving time. Set. For this reason, even when the movement time of the sheet S varies due to component tolerances of individual printers, variations during assembly, and the like, images can be formed on the sheets S at suitable intervals suitable for the individual printers. Thereby, throughput can be improved.

  Further, by setting the image writing interval based on the conveyance time of a plurality of sheets, it becomes possible to detect more accurate variation, and it is possible to improve the throughput more suitably.

  Also, if there are variations in travel time due to changes in the ambient ambient temperature, humidity, and sheet type of the printer, it is possible to form images on the sheet S at suitable intervals by temporarily returning to the initial setting, and throughput Can be improved.

  As mentioned above, although embodiment of this invention was described, this invention is not limited to embodiment mentioned above. In addition, the effects described in the embodiments of the present invention only list the most preferable effects resulting from the present invention, and the effects of the present invention are not limited to those described in the embodiments of the present invention.

  For example, in the present embodiment, the image writing interval is set using the moving time between two points from the start of feeding of the sheet S to the leading edge detection by the top sensor 27 as the image writing interval at the time of single-sided printing. The invention is not limited to this. The conveyance time between two points may be a movement time between at least two points to the secondary transfer unit.

  In addition, as shown in FIG. 8, when the double-sided printing is performed, the movement time between the two points is determined by the top sensor from the start of starting the drive motor that drives the U-turn conveyance roller pair 65 (see FIG. 8A). 27 may be set by the moving time until the leading edge of the sheet S is detected (see FIG. 8B).

  Further, in the present embodiment, the movement time T ′ of the most recent P (plurality) sheets S is stored in the memory 112 and the image writing interval is set, but based on the movement time of one sheet, An image writing interval may be set.

1 Printer (image forming device)
10 Image forming unit (image forming means)
11a to 11d Image forming unit (toner image forming means)
12a to 12d Photosensitive drum (image carrier)
13 Intermediate transfer belt (toner image transfer means)
20 Sheet feeding section (sheet feeding means)
30 Secondary transfer section (toner image transfer means)
110 Control unit (control means)
120 Temperature sensor 130 Humidity sensor 140 Sheet discrimination sensor (sheet discrimination means)
150 timer (travel time detection means)

Claims (6)

Sheet feeding means for feeding sheets;
An image forming unit comprising: a toner image forming unit that forms a toner image on the image carrier; and a toner image transfer unit that transfers the toner image formed on the image carrier to a sheet;
A moving time detecting means capable of detecting a moving time of the sheet between two points to the toner image transferring means;
When continuously forming images on a sheet, if the moving time detected by the moving time detecting unit is shorter than a preset time, the toner image forming unit forms a toner image on the image carrier. Control means for making the toner image formation interval to be shorter than a preset initial interval based on the detected moving time,
An image forming apparatus. The control means stores a movement time of a predetermined number of sheets, and sets the toner image formation interval based on the stored movement time of the predetermined number of sheets.
The image forming apparatus according to claim 1. Equipped with a temperature sensor that can detect the ambient temperature,
When the change amount of the ambient temperature within a predetermined time exceeds a predetermined change amount, the control unit returns the toner image formation interval during continuous printing to the initial interval.
The image forming apparatus according to claim 1, wherein the image forming apparatus is an image forming apparatus. Equipped with a humidity sensor that can detect atmospheric humidity,
The control means returns the toner image formation interval during continuous printing to the initial interval when the amount of change in atmospheric humidity within a predetermined time exceeds a predetermined amount of change.
The image forming apparatus according to claim 1, wherein the image forming apparatus is an image forming apparatus. A sheet discriminating means capable of discriminating the type of the sheet
When the control unit detects that the sheet type has changed, the control unit returns the toner image formation interval during continuous printing to a preset initial interval.
The image forming apparatus according to claim 1, wherein the image forming apparatus is an image forming apparatus. The sheet discriminating unit discriminates the type of the sheet from the rigidity of the sheet;
The image forming apparatus according to claim 5.

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