JP6521746B2 - Image forming device - Google Patents

Description

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

  As a fixing device mounted on an image forming apparatus such as a copying machine or a printer using an electrophotographic technique, one having a configuration in which a fixing roller is heated from the outer peripheral surface is known. Generally, this fixing device has a fixing roller, a heating rotating body that contacts the fixing roller to heat the fixing roller, and a pressure roller that contacts the fixing roller to form a nip. The recording material on which the toner image is formed at the nip portion is conveyed and heated to fix the toner image on the recording material. As a heating rotating body of this fixing device, there are those having a tubular film and a heater contacting the inner surface of the film, and those having a heating roller containing a halogen heater.

  By the way, in this fixing device, there may occur a phenomenon called offset in which a part of toner on the recording material is transferred to the outer peripheral surface of the fixing roller. Here, the offset toner is referred to as offset toner. The offset toner may be transferred to the surface of the heating rotator as the fixing roller rotates and may be accumulated on the surface of the heating rotator. The accumulated toner sometimes returns to the surface of the fixing roller 30 periodically and contaminates the toner image on the recording material.

  Therefore, Patent Document 1 discloses a fixing device which makes non-adhesiveness of a heating member (heating rotary member) as an external heating member to toner on a recording material higher than non-adhesiveness to a fixing roller. In this fixing device, since the adhesion between the offset toner and the fixing roller exceeds the adhesion between the offset toner and the heating member, the offset toner of the fixing roller does not adhere to the heating member and easily stays on the surface of the fixing roller. Become. Thus, the offset toner on the surface of the fixing roller can be fixed to the recording material and discharged as the fixing roller rotates.

Unexamined-Japanese-Patent No. 2003-114583

  However, it may not be sufficient just to make the non-adhesiveness of the external heating member different from the non-adhesiveness of the fixing roller surface, and there is a problem that the offset toner adheres to the external heating member. Therefore, there is a need for an image forming apparatus that can clean the offset toner attached to the external heating member.

  In order to achieve the above object, according to the present invention, an image forming portion for forming a toner image on a recording material, a roller, a heating member for contacting the roller to heat the roller, and the roller in the rotational direction of the roller And a backup member which contacts a position different from the heating member to form a nip portion, heats while conveying the recording material on which the toner image is formed in the nip portion, and fixes the toner image on the recording material An image forming apparatus, comprising: a fixing unit; a temperature detection unit that detects the temperature of the heating member; and a control unit that controls power supplied to the heating member so that the temperature detected by the temperature detection unit becomes a target temperature. In the apparatus, in the case of continuously fixing a plurality of recording materials, the control unit performs at least at least an interval between an interval between a preceding recording material and a subsequent recording material in the nip portion. Characterized by higher than the target temperature the target temperature in the first period parts in the second period for conveying the recording material in said nip.

  According to the present invention, the offset toner attached to the external heating member can be cleaned.

FIG. 2 is a schematic cross-sectional view showing a schematic configuration of a transverse side surface of the image forming apparatus. FIG. 1 is a schematic cross-sectional view showing a schematic configuration of a fixing device in Embodiment 1. FIG. 2 is a schematic cross-sectional view showing a schematic configuration of a ceramic heater used for a fixing device in Embodiment 1. FIG. 6 is an explanatory view showing a ceramic heater and an energization control system used for the fixing device in Embodiment 1. FIG. 5 is a schematic cross-sectional view for explaining an accumulation path of contamination toner in the fixing device. FIG. 7 is a view for explaining a toner attached to the recording material S after completion of Experiment 1 procedure (3) in the image forming apparatus in Example 1, and a density measurement position in Experiment 1 procedure (4). 6 is a graph showing the discharge amount on the recording material S measured in Experiment 1 procedure (4) in the image forming apparatus in Example 1. 10 is a graph showing measured values of concentration of toner adhering to the heating film 16 measured in Experiment 1 procedure (5) in the image forming apparatus in Example 1. 6 is a graph showing the density of toner adhering to the recording material S measured in Experiment 2 procedure (4) in the image forming apparatus in Example 1. FIG. 10 is a graph showing measured values of concentration of toner adhering to the heating film 16 measured in Experiment 2 procedure (5) in the image forming apparatus in Example 1. FIG. 14 is a schematic view for explaining a path along which the contamination toner in close contact with the heating film 16 is peeled off and transferred to the fixing roller in the heating nip. 6 is a graph showing the density of toner adhering to the recording material S measured in the procedure (4) of Experiment 3 in the image forming apparatus in Example 1. 10 is a graph showing measured values of concentration of toner adhering to the heating film 16 measured in the procedure (5) of Experiment 3 in the image forming apparatus in Example 1. 7 is a graph showing temperature transition of each fixing member when the heating operation is started 1 second after continuous printing in the image forming apparatus in Embodiment 1. 7 is a graph showing temperature transition of each fixing member when the heating operation is started after 180 seconds of continuous printing in the image forming apparatus in Embodiment 1. 7 is a graph showing temperature transition of each fixing member when the heating operation is started after 600 seconds of continuous printing in the image forming apparatus in Embodiment 1. 7 is a timing chart of a cleaning sequence performed by the image forming apparatus in Embodiment 1. FIG. 18 is a diagram for explaining an offset evaluation image in Experiment 5 It is the graph which showed the relationship between image density and offset density in Experiment 5 It is a figure explaining a video controller It is a figure explaining an image data processing flow. 7 is a flowchart for detecting image information and determining a cleaning sequence condition in the image forming apparatus in Embodiment 2. 15 is a flowchart for detecting image information and determining a cleaning sequence condition in the image forming apparatus in the third embodiment. 15 is a flowchart for detecting image information and determining a cleaning sequence condition in the image forming apparatus in the fourth embodiment. 14 is a timing chart of a cleaning sequence performed by extending the sheet interval in the image forming apparatus in Embodiment 4. 15 is a flowchart for detecting image information and determining a cleaning sequence condition in the image forming apparatus in the fifth embodiment. 6 is a timing chart illustrating an image forming process using an image data processing notice time. 15 is a flowchart for detecting image information and determining a cleaning sequence condition in the image forming apparatus in the sixth embodiment. 18 is a flowchart for detecting image information and determining a cleaning sequence condition in the image forming apparatus in the seventh embodiment.

Example 1
(1) Image Forming Apparatus An image forming apparatus according to the present invention will be described.

  FIG. 1 shows an image forming apparatus P used in this embodiment, and includes a conveyance path 3 for a recording material S, and four image forming stations 3Y, 3M, 3C, 3K arranged substantially linearly. Is equipped. Of the four image forming stations 3Y, 3M, 3C, and 3K, 3Y is an image forming station for forming a yellow (hereinafter abbreviated as Y) image. 3M is an image forming station for forming an image of magenta (hereinafter abbreviated as M) color. 3C is an image forming station for forming an image of cyan (hereinafter abbreviated as C) color. 3K is an image forming station for forming a black (hereinafter abbreviated as K) color image.

  Each of the image forming stations 3Y, 3M, 3C, 3K includes a drum-shaped electrophotographic photosensitive member (hereinafter referred to as a photosensitive drum) 4Y, 4M, 4C, 4K as an image carrier, and a charging roller 5Y as a charging unit. , 5M, 5C, 5K. Each of the image forming stations 3Y, 3M, 3C, 3K includes an exposure unit 6 as an exposure unit, a developing unit 7Y, 7M, 7C, 7K as a developing unit, and a cleaning unit 8Y, 8M, 8C as a cleaning unit. , 8K. When the video controller 300 receives image information from an external device (not shown) such as a host computer, the video controller 300 transmits a print signal to the control means 31, and an image forming operation is started. At the time of image formation, the photosensitive drum 4Y is rotated in the arrow direction at the image forming station 3Y. First, the outer peripheral surface (surface) of the photosensitive drum 4Y is uniformly charged by the charging roller 5Y, and the charged surface of the photosensitive drum 4Y is exposed by irradiating the laser beam according to the image data by the exposure device 6 The electrostatic latent image is formed. The latent image is developed into a Y toner image by the developing device 7 Y using Y toner. Thus, a Y toner image is formed on the surface of the photosensitive drum 4Y. The same image forming process is performed in the image forming stations 3M, 3C and 3K. As a result, the M toner image is formed on the surface of the photosensitive drum 4M, the C toner image is formed on the surface of the photosensitive drum 4C, and the K toner image is formed on the surface of the photosensitive drum 4K.

  An endless intermediate transfer belt 9 provided along the arrangement direction of the image forming stations 3Y, 3M, 3C, 3K is stretched around a drive roller 9a, a driven roller 9b and a driven roller 9c. The drive roller 9a rotates in the direction of the arrow in FIG. Thus, the intermediate transfer belt 9 is rotationally moved at a speed of 100 mm / sec along the image forming stations 3Y, 3M, 3C, 3K. Each color is formed on the outer peripheral surface (surface) of the intermediate transfer belt 9 by primary transfer means 10Y, 10M, 10C, 10K opposed to the photosensitive drums 4Y, 4M, 4C, 4K with the intermediate transfer belt 9 interposed therebetween. The toner images of are sequentially transferred in an overlapping manner. As a result, a full color toner image of four colors is formed on the surface of the intermediate transfer belt 9.

  The transfer residual toner remaining on the surfaces of the photosensitive drums 4Y, 4M, 4C, 4K after the primary transfer is removed by a cleaning blade (not shown) provided in the cleaning devices 8Y, 8M, 8C, 8K. Thus, the photosensitive drums 4Y, 4M, 4C, and 4K prepare for the next image formation.

  On the other hand, the recording material S stacked and stored in the feeding cassette 11 provided at the lower part of the image forming apparatus P is separated and fed one by one from the feeding cassette 11 by the feeding roller 12 and supplied to the registration roller pair 13. Will be sent. The registration roller pair 13 feeds the fed recording material S to a transfer nip portion between the intermediate transfer belt 9 and the secondary transfer roller 14. The secondary transfer roller 14 is disposed to face the driven roller 9 b with the intermediate transfer belt 9 interposed therebetween. A bias is applied to the secondary transfer roller 14 from a high voltage power supply (not shown) when the recording material S passes through the transfer nip portion. As a result, a full color toner image is secondarily transferred from the surface of the intermediate transfer belt 9 to the recording material S passing through the transfer nip portion. The configuration for forming a toner image on the recording material described above is referred to as an image forming unit.

  The recording material S carrying the toner image is conveyed to the fixing device F1. The recording material S is heated and pressurized by passing through the fixing device F 1, and the toner image is heat-fixed on the recording material S. Then, the recording material S is discharged from the fixing device F1 to the discharge tray 25 outside the image forming apparatus (printer) P.

  The transfer residual toner remaining on the surface of the intermediate transfer belt 9 after the secondary transfer is removed by the intermediate transfer belt cleaning device 26. Thus, the intermediate transfer belt 9 prepares for the next image formation.

  The movement of the recording material S can be detected by the top sensor 40 provided in the vicinity of the registration roller pair 13 and the paper discharge sensor 41 provided between the fixing device F 1 and the paper discharge tray 15.

  In continuous printing, the distance between the preceding recording material S and the subsequent recording material S (paper interval) can be estimated from the distance the recording material S passes through the top sensor 40.

  Further, the timing when the recording material S reaches the fixing device F1 and the timing when it is discharged can be estimated from the timing when the recording material S passes through the top sensor 40 and the feed speed of the recording material S. The discharge sensor 41 can confirm that the recording material S is discharged from the fixing device F1 to the discharge tray.

(2) Fixing device F1 (fixing unit)
In the following description, regarding the fixing device and members constituting the fixing device, the longitudinal direction is a direction orthogonal to the recording material conveyance direction on the surface of the recording material. The short direction is a direction parallel to the recording material conveyance direction on the surface of the recording material. Length is the dimension in the longitudinal direction. The width is a dimension in the lateral direction.

  FIG. 2 is a schematic cross-sectional view showing a schematic configuration of the fixing device F1 according to the present embodiment. FIG. 3 is a schematic cross-sectional view showing a schematic configuration of the ceramic heater 15 used in the fixing device F1 according to the present embodiment. FIG. 4 is an explanatory view showing the ceramic heater 15 and the energization control system. The fixing device F1 shown in the present embodiment is an external heating type fixing device. The fixing device F1 includes a fixing roller (roller member) 30 as a fixing rotating body, a heating unit 10 as a heating unit, and a pressure unit 50 as a backup unit. The fixing roller 30 is a member elongated in the longitudinal direction.

  The fixing roller 30 has a round shaft cored bar 30A made of a metal material such as iron, SUS, or aluminum. An elastic layer 30B mainly composed of silicone rubber is formed on the outer peripheral surface of the core 30A, and a release layer 30C mainly composed of PTFE, PFA or FEP is formed on the outer peripheral surface of the elastic layer 30B. It is formed. The fixing roller 30 is rotatably supported at both longitudinal end portions of the core 30A by side plates (not shown) on both sides in the longitudinal direction of an apparatus frame (not shown) via bearings (not shown).

  The heating unit 10 includes a ceramic heater (hereinafter referred to as a heater) 15 as a heating source, a cylindrical heating film (endless film) 16 as a heating member, and a heating film guide 19 as a first support member. Have. The heating film guide 19 is formed in a substantially concave shape in cross section using a predetermined heat-resistant material. Then, both end portions in the longitudinal direction of the heating film guide 19 are supported by the side plates on both sides in the longitudinal direction of the apparatus frame. The heater 15 is supported by a groove provided on the flat surface of the heating film guide 19 along the longitudinal direction of the heating film guide 19 and the heating film 16 is loosely fitted on the heating film guide 19 supporting the heater 15. There is. The heater 15, the heating film 16, and the heating film guide 19 are all members which are long in the longitudinal direction.

  The heater 15 has a thin plate-like heater substrate 15A mainly composed of ceramic such as alumina and aluminum nitride. On the substrate surface of the heater substrate 15A on the heating film 16 side, a heating resistor 15B mainly composed of silver, palladium or the like is provided along the longitudinal direction of the heater substrate 15A. Further, on the surface of the substrate, a protective layer 15C mainly composed of glass or a heat-resistant resin such as fluorine resin or polyimide is provided so as to cover the heating resistor 15B.

  The heating film 16 is formed such that the inner circumferential length of the heating film 16 is longer by a predetermined length than the outer circumferential length of the heating film guide 19, and is externally fitted to the heating film guide 19 loosely without tension. As a layer configuration of the heating film 16, a two-layer structure in which an outer peripheral surface of an endless band-like film base layer mainly composed of polyimide is covered with an endless band-like surface layer mainly composed of PFA is adopted.

  The heating unit 10 is disposed in parallel with the fixing roller 30 above the fixing roller 30 in FIG. Both end portions in the longitudinal direction of the heating film guide 19 are biased in a direction orthogonal to the generatrix direction of the fixing roller 30 by a pressure spring (not shown). The heating film 16 is brought into contact (abutment) with the outer peripheral surface (surface) of the fixing roller 30 on the outer surface of the protective layer 15 C of the heater 15 and the heating film guide 19. Thereby, the elastic layer 30B of the fixing roller 30 is crushed and elastically deformed at a position corresponding to the outer surface of the protective layer 15C of the heater 15, and the predetermined width is heated by the surface of the fixing roller 30 and the outer peripheral surface (surface) of the heating film 16. A nip portion (pressure contact portion) N2 is formed. Accordingly, the fixing roller 30 and the heating film guide 19 and the heater 15 sandwich the heating film 16 to form the heating nip portion N2.

  The pressure unit 50 (backup member) includes a cylindrical pressure film (endless film) 51 as a pressure rotator, a pressure film guide 52 as a second support member, and the like. The pressure film guide 52 is formed in a substantially concave shape in cross section using a predetermined heat-resistant material. And both ends in the longitudinal direction of the pressure film guide 52 are supported by the side plates on both sides in the longitudinal direction of the apparatus frame. The pressure film 51 is loosely fitted on the pressure film guide 52. The pressure film 51 and the pressure film guide 52 are both members which are long in the longitudinal direction.

  The pressure film 51 is formed such that the inner circumferential length of the pressure film 51 is longer than the outer circumferential length of the pressure film guide 52, and is externally fitted to the pressure film guide 52 loosely without tension. As a layer configuration of the pressure film 51, a two-layer structure is adopted in which the outer peripheral surface of an endless band-like film base layer mainly composed of polyimide is covered with an endless band-like surface layer mainly composed of PFA.

  The pressure unit 50 is disposed in parallel with the fixing roller 30 below the fixing roller 30 in FIG. Then, both end portions in the longitudinal direction of the pressure film guide 52 are urged in a direction orthogonal to the generatrix direction of the fixing roller 30 by a pressure spring (not shown), and the pressure film 51 is pressed by the flat surface 52A of the pressure film guide 52. Is brought into contact (contact) with the surface of the fixing roller 30 in a pressurized state. Thereby, the elastic layer 30B of the fixing roller 30 is crushed and elastically deformed at a position corresponding to the flat surface 52A of the pressure film guide 52, and the surface of the fixing roller 30 and the outer peripheral surface (surface) of the pressure film 51 have a predetermined width. A fixing nip portion N1 is formed. Accordingly, the fixing roller 30 forms a fixing nip portion N1 together with the pressure film 51. The pressure unit 50 contacts the fixing roller 30 at a position different from the heating unit 10 in the rotational direction of the fixing roller 30, and forms a nip portion N1.

  The heat fixing operation of the fixing device F1 will be described with reference to FIGS. 2 and 4. The control means 31 rotationally drives a drive motor (not shown) as a drive source in accordance with an image forming sequence executed in response to a print command. The rotation of the output shaft of the drive motor is transmitted to the core metal 30A of the fixing roller 30 via a predetermined gear train (not shown). Thus, the fixing roller 30 is rotated at a predetermined circumferential speed (process speed) in the arrow direction. The rotational drive of the fixing roller 30 is transmitted to the pressure film 51 by the frictional force generated between the surface of the fixing roller 30 and the surface of the pressure film 51 at the fixing nip portion N1. As a result, the pressure film 51 rotates in the direction of the arrow following the rotation of the fixing roller 30 while the inner circumferential surface (inner surface) of the pressure film 51 contacts the flat surface 52A of the pressure film holder 52. The rotational drive of the fixing roller 30 is transmitted to the heating film 16 by the frictional force acting between the surface of the fixing roller 30 and the surface of the heating film 16 at the heating nip portion N2. As a result, the heating film 16 rotates in the direction of the arrow following the rotation of the fixing roller 30 while the inner peripheral surface (inner surface) of the heating film 16 contacts the outer surface of the protective layer 15C of the heater 15.

  The CPU 23 (control unit) turns on the triac 20 in accordance with the image forming sequence. The triac 20 controls the power applied from the AC power supply 21 and starts energization (power supply) to the heating resistor 15B of the heater 15. The heating resistor 15B generates heat as a result of this energization, and the heater 15 rapidly raises the temperature to heat the heating film 16. The temperature of the heater 15 is detected by a thermistor 18 as a temperature detection member (temperature detection unit) provided on the substrate surface of the heater substrate 15A on the heating film guide 19 side. The CPU 23 takes in an output signal (temperature detection signal) from the thermistor 18 through the A / D conversion circuit 22, and based on this output signal, the TRIAC 20 maintains the heater 15 at a predetermined fixing temperature (target temperature). Control. As a result, the heater 15 is temperature-controlled (controlled) so that the temperature detected by the thermistor 18 becomes the target temperature.

  The surface of the rotating fixing roller 30 is heated by the heater 15 through the heating film 16 at the heating nip N2. As a result, a sufficient amount of heat is applied to the surface of the fixing roller 30 for heating and fixing the unfixed toner image T carried by the recording material S at the fixing nip portion N1. In a state in which the drive motor is driven to rotate and the heater 15 is adjusted in temperature, the recording material S carrying the unfixed toner image T is introduced to the fixing nip N1 with the toner image bearing surface facing upward. The recording material S is nipped by the surface of the fixing roller 30 and the surface of the pressure film 51 at the fixing nip portion N1 and is conveyed (nipped and conveyed) in that state. In the conveyance process, the toner image T is heated and melted on the surface of the fixing roller 30, and a nip pressure is applied to the melted toner image T by the fixing nip portion N1, whereby the toner image T on the surface of the recording material S It is heat fixed.

(Toner contamination problem)
In the above-described heating and fixing operation, when the toner image T on the recording material S is heated and fixed at the fixing nip portion N1, part of the toner on the recording material S is transferred to the outer peripheral surface (surface) of the fixing roller 30 The phenomenon of offset occurs. The offset toner attached to the surface of the fixing roller 30 contacts the surface of the heating film 16 at the heating nip N2 with the rotation of the fixing roller 30, and also adheres to the surface of the heating film 16. In addition, paper fibers contained in the recording material S and paper powder such as fillers (fillers) made of inorganic substances such as calcium carbonate and talc fall off and adhere to the surface of the fixing roller 30 and are also transferred to the surface of the heating film 16 . The toner and paper powder on the heating film 16 mix and accumulate on the surface of the heating film 16 (see FIG. 5). The toner attached to and accumulated on the surface of the heating film 16 is hereinafter referred to as contamination toner Tc.

  The contamination toner Tc reduces the non-stickiness of the surface of the heating film 16 and collects toner and paper dust to further grow. Contamination toner Tc accumulated on the surface of the heating film 16 moves to the surface of the fixing roller 30 depending on conditions, and is transferred to the recording material S to cause an image defect.

(Experiment 1)
The experiment was conducted with the image forming apparatus P and the fixing device F1 described in the present embodiment, and the condition for discharging the contamination toner Tc accumulated on the heating film 16 onto the recording material S was confirmed. The process speed of the image forming apparatus used in the experiment is 100 mm / s, and the distance between the preceding recording material S and the next recording material S (sheet interval) is 30 mm. The fixing device F1 is the fixing device F1 used in this embodiment, and the temperature adjustment temperature of the heater 15 is 200.degree.

  The experiment was performed by the following procedure.

(Experimental procedure (1))
Continuous printing of 250 sheets is performed by the image forming apparatus and fixing device F1.

(Experimental procedure (2))
After continuous printing is completed and the last recording material S is discharged from the fixing nip and the discharge sensor detects it, the fixing device F1 is rotationally driven while controlling the heater 15 to maintain the predetermined target temperature. The roller 30, the heating film 16, and the pressing film 51 are rotated. Hereinafter, rotating the fixing device F1 in a state where the recording material S is not nipped and conveyed by the fixing nip is referred to as idle rotation. The toner attached to the heating film 16 is transferred to the fixing roller 30 and removed from the heating film 16 by a mechanism described later. After 5 seconds, the energization of the heater 15 is stopped, and the rotational driving of the fixing device F1 is stopped.

  The heating and idling operation of rotating the recording material S in a state where the recording material S is not nipped and conveyed by the fixing nip while heating to the target temperature is hereinafter referred to as a cleaning sequence.

(Experimental procedure (3))
In order to confirm the contamination toner Tc removed from the heating film 16, one recording material S on which no toner is placed is printed in the image forming unit.

(Experimental procedure (4))
After printing, the concentration of the contamination toner Tc discharged onto the recording material S is measured with a densitometer (X-Rite 504 measurement mode Status-I manufactured by X-Rite).

(Experimental procedure (5))
After completion of the procedure (4), the heating film 16 is removed from the fixing device F1, and the amount of contamination toner Tc remaining on the surface of the heating film 16 is measured. After sticking a cellophane adhesive tape (Nichiban CT-18) on the surface of the heating film 16 to which the contamination toner Tc has been adhered, the contamination toner Tc is peeled off. The contamination toner Tc attached to the cellophane adhesive tape is measured with a densitometer (X-Rite 504 measurement mode Status-I manufactured by X-Rite). The printed image T is a text pattern in which seven lines of 12-point characters are printed with each of yellow toner (Y toner), magenta toner (M toner), cyan toner (C toner), and black toner (K toner). The printing rate is 1% for each color. The top, bottom, left, and right 5 mm are margins. For the experiments, general LBP printing paper, basis weight 80 g / m ² , A4 (width 210 mm vertical 297 mm) size paper was used. The experiment was performed by shaking the control temperature at the time of the cleaning sequence of the experimental procedure (2). The experiment was conducted under the conditions of 200 ° C., which is the same as the printing conditions, and 210 ° C., 220 ° C., and 230 ° C., which are the same as the printing conditions. After the completion of the test procedure (3), toner was attached to the printed recording material S as shown in FIG. In the experimental procedure (4), the toner attached to the recording material S is measured at a plurality of points, and the darkest portion of the density is measured.

  The experimental results are shown in FIG. 7 and FIG. FIG. 7 is a graph showing the discharge amount on the recording material S measured in the experimental procedure (4). The horizontal axis of the graph is the temperature adjustment temperature of the cleaning sequence, and the vertical axis is the density of the toner deposited on the recording material S after the cleaning sequence. The solid line is the result of density measurement on the front side of the recording material S, and the dotted line is the result of density measurement on the back side of the recording material S. The higher the temperature adjustment temperature of the cleaning sequence, the higher the concentration of toner deposited on the recording material S. In particular, the toner density on the back side of the recording material S is high. FIG. 8 is a graph showing measured values of toner concentration deposited on the heating film 16 measured in the experimental procedure (5). The horizontal axis of the graph is the control temperature of the cleaning sequence, and the vertical axis is the toner concentration on the heating film 16 remaining after the cleaning sequence. The higher the temperature adjustment temperature of the cleaning sequence, the lower the toner concentration remaining on the heating film 16.

(Experiment 2)
In the same image forming apparatus P and fixing device F1 as in Experiment 1, the experiment was performed while changing the time of the cleaning sequence performed in Procedure 2 of Experiment 1. The experiment was conducted under the conditions of a temperature adjustment temperature of 230 ° C. and a heating rotation time of 0 seconds (none), 5 seconds, and 10 seconds. Other experimental procedures are similar. The experimental results are shown in FIG. 9 and FIG. FIG. 9 is a graph showing the concentration of toner deposited on the recording material S measured in the procedure (4) of the experimental procedure 2. The horizontal axis of the graph is the heating rotation time of the cleaning sequence, and the vertical axis is the density of the toner deposited on the recording material S after the cleaning sequence. The solid line is the result of density measurement on the front side of the recording material S, and the dotted line is the result of density measurement on the back side of the recording material S. FIG. 10 is a graph showing the measured values of the toner concentration deposited on the heating film 16 measured in the procedure (5) of Experiment 2. The horizontal axis of the graph is the heating idle rotation time of the cleaning sequence, and the vertical axis is the toner concentration on the heating film 16 remaining after the cleaning sequence.
As the heating rotation time of the cleaning sequence is longer, the toner concentration on the recording material S is higher. In addition, the toner concentration remaining on the heating film 16 was lowered. By printing after the cleaning sequence, the toner adheres to the recording material. When the density of the toner attached to the recording material increases, conversely, the density of the toner attached to the heating film 16 decreases.
Contamination toner Tc is accumulated on the heating film 16 by the continuous printing of the experimental procedure (1). Contamination toner Tc of the heating film 16 is transferred to the fixing roller 30 and the pressure film 51 by the cleaning sequence of the experimental procedure (2). Then, the contamination toner Tc transferred to the fixing roller 30 and the pressure film 51 at the next printing is transferred to the recording material S and output to the outside of the apparatus. It can be seen that the discharge amount from the heating film 16 is larger as the target temperature adjustment temperature of the cleaning sequence is higher and the heating rotation time is longer.

(mechanism)
The mechanism by which the contamination toner Tc on the surface of the heating film 16 is transferred to the surface of the fixing roller 30 and further transferred to the surface of the pressure film 51 by the cleaning sequence will be described.
The toner containing resin as a main component is softened and becomes easy to adhere to the contacting member when heat is applied, but it is melted when the temperature is further raised, and the cohesion of the toners is reduced to make contact. It is easy to peel off from the The mechanism by which the contamination toner Tc in close contact with the heating film 16 is peeled off at the heating nip N2 and transferred to the fixing roller 30 will be described with reference to FIG.
(1) The contamination toner Tc adhering to the surface of the heating film 16 reaches the heating nip N2 as the heating film 16 rotates. In the heating nip N2, the sheet is heated from the heating film 16 side in a state of being sandwiched by both the heating film 16 and the fixing roller 30.
(2) When the contamination toner Tc is heated excessively by the heating film 16 at the heating nip N2 and excessively melted, the aggregation toner is easily broken at the interface and the contamination toner Tc is easily peeled off from the heating film 16 .
(3) Also on the contact surface between the fixing roller 30 and the contamination toner Tc, when the contamination toner Tc is heated, it softens and adheres to the fixing roller 30.
(4) At the interface between the surface of the heating film 16 and the contamination toner Tc, the contamination toner Tc melts and the cohesion also decreases compared to the interface between the surface of the fixing roller 30 and the contamination toner. The contamination toner Tc transfers from the high temperature side to the low side due to the difference in the cohesion of the toner at the interface. As the temperature difference between the surface temperature of the heating film 16 and the surface temperature of the fixing roller 30 increases, the transfer becomes easier.
(5) By the same mechanism, the contamination toner Tc transferred onto the fixing roller 30 is transferred to the pressure film 51 whose temperature is lower.
(6) The transferred contamination toner Tc is transferred from the fixing roller 30 to the surface of the recording material S, from the pressure film 51 to the back surface of the recording material S, and fixed as a dirt toner.

  While the contamination toner Tc is heated on the surface of the heating film 16, the wax component and the low molecular weight component are volatilized and become less soluble than the toner T on the recording material S.

  By setting the temperature higher than that in the normal printing in the cleaning sequence, and heating for a long time, the contamination toner Tc accumulated on the heating film 16 can be melted. The cohesion between toners can be reduced, and contamination toner Tc not peeled off during sheet feeding can be easily peeled off from the heating film 16.

(Experiment 3)
In the same image forming apparatus P and fixing device F1 as in Experiment 1, the experiment was performed while changing the time from the end of continuous printing to the start of the cleaning sequence. In experimental procedure (2), continuous printing is completed, the last recording material S is discharged from the fixing nip, and the waiting time from when the discharge sensor detects the passage of the recording material S to the start of the cleaning sequence The examination was changed to one second, 180 seconds, and 600 seconds. Other experimental procedures are similar.

  The experimental results are shown in FIG. 12 and FIG. FIG. 12 is a graph showing the concentration of toner adhering to the recording material S measured in the procedure (4) of Experiment 3. The horizontal axis of the graph is the heating idle rotation time of the cleaning sequence, and the vertical axis is the density of the toner deposited on the recording material S after the cleaning sequence. The solid line is the result of density measurement on the front side of the recording material S, and the dotted line is the result of density measurement on the back side of the recording material S.

  FIG. 13 is a graph showing the amount of contamination toner Tc remaining on the heating film 16 measured in the procedure (5) of Experiment 1. FIG. 6 is a graph showing measured values of density of toner adhering to the heating film 16; FIG. The horizontal axis of the graph is the heating idle rotation time of the cleaning sequence, and the vertical axis is the toner concentration on the heating film 16 remaining after the cleaning sequence. As shown in FIGS. 12 and 13, the amount of contamination toner Tc discharged from the heating film 16 to the recording material S changed depending on the waiting time until the cleaning sequence was started. The one second waiting time was the most frequent result.

  Next, the reason why the discharge amount of toner on the heating film 16 is changed depending on the time from the end of the continuous printing to the start of the cleaning sequence will be considered. Therefore, the surface temperature of the heating film 16 and the surface temperature of the fixing roller 30 and the surface temperature of the pressure film 51 were measured during the continuous printing and until the start of the cleaning sequence after the continuous printing. We will discuss each experimental result.

  The case where the cleaning sequence is started with a standby time of 1 second will be described with reference to FIG. FIG. 14 shows temperature transition when the heating operation is started after one second of continuous printing, the solid line indicates the surface temperature of the heating film 16, the broken line indicates the surface temperature of the fixing roller 30, and the dotted line indicates the surface temperature of the pressure film 51. The vertical axis represents the temperature of each member, and the horizontal axis represents time, and the end of printing is zero. During continuous printing, since the heat is applied to the recording material S from the surface of the fixing roller 30 during the heating and fixing operation of the recording material S at the fixing nip N2, the temperature of the surface of the fixing roller 30 is lowered. The cleaning sequence is started from the state where the temperature difference between the surface of the heating film 16 and the surface of the fixing roller 30 is large. Therefore, the temperature difference between the surface of the heating film 16 and the surface of the fixing roller 30 in the cleaning sequence also increases. Since the cleaning sequence is started from the state where the temperature of the surface of the heating film 16 is high, the surface of the heating film 16 reaches the target temperature in a short time, and the contamination toner Tc can be melted.

  The case where the cleaning sequence is started with a standby time of 180 seconds will be described with reference to FIG. FIG. 15 shows temperature transition when the heating operation is started after continuous printing 180 seconds, the solid line indicates the surface temperature of the heating film 16, the broken line indicates the surface temperature of the fixing roller 30, and the dotted line indicates the surface temperature of the pressure film 51. The vertical axis represents the temperature of each member, and the horizontal axis represents time, and the end of printing is zero. After completion of printing, the temperature of each member decreases due to heat radiation. Heat is transferred from the surface of the heating film 16 to the surface of the fixing roller 30, and the temperature difference from the surface of the heating film 16 to the surface of the fixing roller 30 gradually decreases.

  The cleaning sequence is started from the state where the temperature difference from the surface of the heating film 16 to the surface of the fixing roller 30 is smaller than that immediately after printing. The temperature difference between the surface of the heating film 16 and the surface of the fixing roller 30 during the heating operation is not large. It also takes time for the surface of the heating film 16 to reach the target temperature. Therefore, the transfer of the contamination toner Tc from the heating film 16 to the fixing roller 30 is less than the waiting time of 1 second.

  A case where the cleaning sequence is started with a standby time of 600 seconds will be described. At the start of the cleaning sequence, the temperature difference between the surface of the heating film 16 and the surface of the fixing roller 30 is larger than in the case of the standby time 180 seconds, but it takes time until the surface of the heating film 16 reaches the target temperature. As a result, the transfer of contamination toner Tc from the heating film 16 to the fixing roller 30 was less than the waiting time of 1 second.

  As described above, by changing the temperature and timing of the cleaning sequence, it is possible to control the amount of the contamination toner Tc accumulated on the heating film 16 to be discharged from the heating film 16. The higher the temperature, the more effective, and the timing is more effective immediately after the discharge of the recording material S where the temperature difference between the heating film surface and the fixing roller surface becomes large. The timing immediately after the discharge of the recording material S is considered to be the interval between each sheet in the continuous printing except after the last sheet of the print job is discharged. The sheet interval referred to here is a period (first period) in which an interval between a preceding recording material and a following recording material is reached in the case of continuously fixing a plurality of recording materials. A period in which the recording material is conveyed at the fixing nip portion N2 with respect to the sheet interval is referred to as a second period. FIG. 16 shows the temperature transition including the sheet interval during continuous printing, the solid line indicates the surface temperature of the heating film 16, the broken line indicates the surface temperature of the fixing roller 30, and the dotted line indicates the surface temperature of the pressure film 51. The vertical axis represents the temperature of each member, and the horizontal axis represents time. As the front recording material S (preceding sheet) between the sheets passes through the fixing nip N2, the temperature on the surface of the fixing roller 30 decreases, and the difference with the temperature on the surface of the heating film 16 increases. Implementing the cleaning sequence at this timing has the following merits. Since this promotes the transfer of the contamination toner Tc to the fixing roller 30 and can clean each page of the continuous printing, the contamination toner Tc can be discharged little by little. In the present embodiment, a cleaning sequence is performed during a period in which the fixing nip N2 is in the sheet interval during continuous printing.

(Cleaning sequence operation timing)
As described above, in the fixing device of the external heat fixing method, there are the heating nip N2 for heating the fixing roller 30, and the fixing nip N1 for fixing the unfixed toner on the recording material S. In order to transfer the contamination toner Tc from the fixing roller 30 to the pressure film 51 between sheets, the following is performed. Transfer of contamination toner Tc from the heating film 16 to the fixing roller 30 at the heating nip N2 is performed so that the timing at which the fixing nip N1 becomes an inter-sheet interval. That is, the temperature control temperature switching timing for transferring the contamination toner Tc from the heating film 16 to the fixing roller 30 needs to be earlier than the timing between the sheets at the actual fixing nip N1.

FIG. 17 is a timing chart in the case of carrying out the cleaning sequence between sheets.
(1) The trailing edge of the preceding recording material S reaches the top sensor 40 (sensor OFF)
(2) After the top sensor 40 is turned off, the temperature control temperature is switched to the temperature control temperature for cleaning after passing the temperature control temperature for a predetermined time (3) Furthermore, the temperature control temperature for cleaning is used after the predetermined time Switching from Temperature Control Temperature to Temperature Control Temperature During Paper Passing The heating nip N2 in the present embodiment is disposed at a position shifted 180 degrees from the fixing nip N1 in the rotational direction. Therefore, the contamination toner Tc transferred to the fixing roller 30 at the heating nip N2 reaches the fixing nip N1 after a lapse of about half a circumference of the fixing roller 30. In the image forming apparatus P used in this embodiment, the process speed is 100 mm / s, and the distance (paper interval) between the preceding recording material S and the next recording material S is 30 mm. The distance from the top sensor 40 to the fixing nip N1 is 100 mm, and 1000 msec after the trailing edge of the preceding recording material S is detected by the top sensor 40, it passes through the fixing nip N1 and rushes into the sheet. Since the outer circumference of the roller is 54 mm (540 msec), the temperature control at the time of sheet passing is switched to the temperature control temperature for cleaning after 1000 msec− (540 msec / 2) = 730 msec after the top sensor 40 is turned off. Also, after the sheet interval of 30 mm (300 msec) in this embodiment is switched to the temperature control temperature at the time of sheet passing so that the image of the leading end of the following recording material S is not affected by the temperature control temperature set high for cleaning. Then, the control for the fixing process of the subsequent recording material S is entered. Although it is possible to set the temperature adjustment time for cleaning to be shorter than the inter-paper time, the longer the time, the larger the effect of discharging the contamination toner Tc, and in this embodiment the entire inter-paper time is cleaned. Adjust the temperature at the temperature.

(Temperature control temperature for cleaning)
The higher the temperature adjustment temperature for cleaning, the larger the effect of discharging the contamination toner Tc. Therefore, it is preferable to set the temperature as high as possible, but if it is set too high, the control performance may be degraded due to excessive rise in temperature in the image forming apparatus or abrupt temperature control temperature change, resulting in deterioration of the fixability. is there.

  In the present embodiment, from the viewpoint of securing the heat resistance of parts in the image forming apparatus and fixing property, the temperature control temperature at the cleaning sequence is set to 210 ° C., which is 10 ° C. higher than the paper temperature control temperature 200 ° C.

(Experiment 4)
In the image forming apparatus in this embodiment, the contamination toner Tc accumulation suppression effect of the heating film 16 by the cleaning sequence was confirmed. As an image forming apparatus according to the present embodiment, an image forming apparatus A which carries out a cleaning sequence at a temperature of 210 ° C. at a sheet interval timing is prepared, and an image forming apparatus B which does not carry out the cleaning sequence as an image forming apparatus as a comparative example. Prepared.

  Further, in both of the image forming apparatuses A and B, the process speed is 100 mm / s, and the distance (paper interval) between the preceding recording material S and the following recording material S is 30 mm. The temperature adjustment temperature during sheet feeding by the heater 15 in the fixing device F1 is 200.degree.

  In an environment with a temperature of 15 ° C. and a humidity of 15%, an experiment was conducted to print a total of 10000 sheets continuously using the image forming apparatuses A and B, to confirm the presence or absence of image defects and to observe the appearance of the heating film 16 Carried out.

  The printed image T is a text pattern in which 12 lines of 12-point characters are printed for each of yellow toner, magenta toner, cyan toner, and black toner, and the printing rate is 1% for each color. The experimental results are shown in Table 1.

  In the image forming apparatus according to the present embodiment, in the image forming apparatus A subjected to the cleaning sequence, no image defect occurs even after printing 10000 sheets and no contamination toner Tc adheres to the surface of the heating film 16. .

  On the other hand, in the image forming apparatus B in which the cleaning sequence as the comparative example was not performed, when 8,000 sheets were printed, a fixing failure was found in the fixed toner image of the printed recording material S. When the inside of the fixing device was observed, contamination toner Tc was adhered to the surface of the heating film 16.

  As described above, according to this embodiment, accumulation of contamination toner Tc in the heating film can be suppressed.

  In the present embodiment, as an example of the fixing device F1, the configuration of the external heating member in which the ceramic heater 15 as a heating source is built in the heating film 16 has been described.

  The external heating member may be a thin-walled heat roller incorporating a heating source such as a halogen heater, or the surface of the external heating member may generate heat by the inside of the external heating member or an external induction heating device. Moreover, although the pressure film structure using the pressure film 51 as a pressure member was demonstrated, the pressure roller structure which provided the rubber layer on the metal core outer side may be sufficient.

Example 2
Since the basic configuration of the image forming apparatus to which the present invention is applied is the same as that of the first embodiment, elements having the same or corresponding functions and configurations as those of the first embodiment are denoted by the same reference numerals. The description is omitted.

  The image forming apparatus in the present embodiment changes the temperature of the cleaning sequence in accordance with the image to be printed. The higher the temperature adjustment temperature for cleaning, the larger the effect of discharging the contamination toner Tc. However, if the temperature adjustment temperature is too high, the temperature in the image forming apparatus excessively rises, and energy is consumed a lot due to the power supply between sheets.

  By the way, in an image to be printed, there are patterns in which an offset tends to occur in the heat fixing operation and those in which the offset is not so. Therefore, in the case of an image in which contamination toner Tc is likely to be accumulated, the accumulation of contamination toner Tc is suppressed by setting the target temperature of the cleaning sequence high, and in the case of an image which is difficult to offset, the target temperature between sheets is set. Suppress the up. By this, it is possible to suppress an increase in temperature rise and energy consumption in the image easy-to-use device.

(Experiment 5)
An experiment was conducted with the image forming apparatus used in this example, and the image density of the unfixed toner image on the recording material S was changed to confirm the ease of offsetting. The process speed of the image forming apparatus used in the experiment is 100 mm / s, and the distance between the preceding recording material S and the next recording material S (sheet interval) is 30 mm. The fixing device is the heating fixing device used in this embodiment, and the temperature adjustment temperature of the heater 15 is 200.degree. For the experiments, general LBP printing paper, basis weight 80 g / m ² , A4 (width 210 mm vertical 297 mm) size paper was used. As shown in FIG. 18, the unfixed toner image t was formed at 10 mm to 70 mm from the leading edge of the sheet. The offset toner Toff attached to the fixing roller 30 as an unfixed toner image adheres again to the area X1 of 67 mm to 127 mm on the downstream side of the outer peripheral length 57 mm of the fixing roller 30. The density of the image offset to a region X1 of 67 mm to 127 mm from the leading edge of the sheet is measured with a densitometer (X-Rite 504 measurement mode Status-I manufactured by X-Rite). Further, the density of the recording material S on which the image was not formed was also measured, and the density difference between them was regarded as the offset toner density.

  The unfixed toner image T was formed of toners of three colors of yellow toner (Y toner), magenta toner (M toner) and Cian toner (C toner) so as to have an image density of 12 to 240% in total.

  The experimental results are shown in FIG. The horizontal axis is the image density of the unfixed image t, and the vertical axis is the density of the offset image. In the halftone region where the image density is 20% to 80% (predetermined density range), the amount of offset generation is large. In the halftone region image, the toner density is low, and the toners are not closely connected with each other. Therefore, it is considered that the offset from the recording material S to the fixing roller is large.

  Therefore, the target temperature of the cleaning sequence is set high in the halftone region in which the density of the image is within the predetermined density range, and the temperature change between the sheets is set small when the density of the image is out of the predetermined density range. This stabilizes the control of the heater and reduces the influence of the subsequent recording material S on the image.

(Image processing means)
The video controller 300 as an image processing means will be described using the diagram shown in FIG. The video controller 300 includes devices such as a host interface unit 302, an image forming apparatus interface unit 303, a ROM 304, a RAM 305, and a CPU 306, which are mutually connected via a CPU bus 301. The CPU bus 301 includes an address, data and control bus.

  The host interface unit 302 has a function of bidirectionally connecting to a data transmission apparatus such as a host computer via a network. The image forming apparatus interface unit 303 has a function of performing bidirectional communication connection with the image forming apparatus P.

  The ROM 304 holds control program code for executing image data processing to be described later and other processing. A RAM 305 is a memory for holding bitmap data and image density information as a result of rendering image data received by the image forming apparatus interface unit 303, and temporarily holding a buffer area and various processing statuses. . The CPU 306 controls each device connected to the CPU bus 301 based on the control program code stored in the ROM 304.

(Image data processing and detection of image density information)
The image data processing will be described. FIG. 21 shows an image data processing flow. From the host computer, commands such as paper size and operation mode are sent together with the image data as image information (processing S10). When the image data relates to a color image, it is in the form of color information by RGB (red, green, blue) data, and each color information is allocated to device RGB data that can be reproduced by this apparatus and converted. Is performed (processing S11). Subsequently, color information of the image data is converted from device RGB data to device YMCK (yellow, magenta, cyan, black) data (processing S12). This YMCK data is defined to represent the ratio of the toner amount to the toner amount obtained on the transfer material when the laser of each color image forming station is fully lit, and has a width of 0% to 100%. A data value of 0% means that the laser is completely turned off and the toner amount is zero.

  Here, with respect to YMCK data, the exposure amounts of Y, M, C, and K colors are calculated using a gradation table that indicates the relationship between the exposure amount of each color and the amount of toner actually used. The image density is calculated from the YMCK data, for example, if the image data at a pixel is Y = 50%, M = 70%, C = 20%, K = 0%, the image density is 140% (= 50 + 70 + 20 + 0). Thereafter, for each pixel, the exposure amount of each color is converted into an exposure pattern to be actually used (processing S14), and an exposure output is obtained (processing S15).

  Next, the method of determining the cleaning sequence in the present embodiment will be described in detail.

  FIG. 22 is a flowchart in which the image forming apparatus detects image information and determines the temperature setting of the cleaning sequence. When receiving the image information, the video controller 300 transmits a print signal to the control means 31, and starts an image forming operation on the preceding recording material S (S21). At the same time, the acquisition unit acquires each pixel density information of the image to be formed on the recording material S (S22), and detects whether there is any pixel whose image density is in the range of 20 to 80% (S23) . When there is no pixel whose image density is in the range of 20 to 80%, the sheet interval with the subsequent recording material S immediately after that is set to 205 ° C. raised 5 ° C. from the temperature control temperature at the time of sheet passing ( S24). If there is a pixel whose image density is in the range of 20 to 80%, it is set to 210.degree. C., which is raised by 10.degree. C. (S25). Then, the temperature control temperature is switched at the timing when the contamination toner arrives at the sheet between the fixing nips (S26). It is determined whether the subsequent recording material S is the last sheet of the job (S27). If it is the last sheet, the cleaning sequence is ended (S28), and if there is a subsequent recording material, image density information is acquired again (S23), and the image formation of the subsequent recording material S is started. Then, at the same time, each pixel density information of the image to be formed on S is acquired, it is detected whether or not there is a pixel whose image density is in the range of 20 to 80%, and the next controlled temperature is determined.

(Experiment 6)
In the image forming apparatus according to this embodiment, the presence or absence of the occurrence of the image defect due to the cleaning sequence and the effect of the cleaning sequence were confirmed. As an image forming apparatus according to the present embodiment, an image forming apparatus C is provided which changes the temperature of the cleaning sequence in accordance with the image density to be printed. As a comparative example to the present embodiment, an image forming apparatus D in which the temperature control temperature for cleaning is always set to 210 ° C. regardless of the image density and an image forming apparatus E not performing the cleaning sequence are prepared. The image forming apparatuses C to E are the same as those used in Experiment 1, the process speed is 100 mm / s, and the distance (sheet interval) between the preceding recording material S and the following recording material S is 30 mm. The temperature adjustment temperature at the time of sheet feeding by the heater 15 in the fixing device F1 is 200.degree. In an environment of a temperature of 15 ° C. and a humidity of 15%, an experiment was conducted to print a total of 500 sheets continuously using the image forming apparatuses C, D and E. As the printed image T, a text pattern in which 12 lines of 12-point characters are printed for each of the yellow toner, magenta toner, cyan toner, and black toner used in Experiment 5 was used. Furthermore, in the present example, a full halftone (HT) pattern of 60% image density formed of Black toner was also used. Table 2 shows the inter-sheet temperature control temperature for cleaning up to the eighth page, the presence or absence of an image defect, and the appearance confirmation result of the heating film 16 when printing is alternately performed on the text pattern and the entire HT pattern.

  Even when 500 sheets of the image forming apparatus C and the image forming apparatus D of the present embodiment perform continuous printing, contamination toner Tc did not adhere to the surface of the heating film 16.

  On the other hand, in the image forming apparatus E of the comparative example, when 300 sheets were printed, a fixing failure was found in the fixed toner image of the printed recording material S. When the inside of the fixing device was observed, contamination toner was adhering to the surface of the heating film 16.

  As described above, according to this embodiment, it is possible to suppress the contamination toner Tc accumulation of the heating film while suppressing the excessive temperature rise and the energy consumption more than necessary in the image forming apparatus.

[Example 3]
Since the basic configuration of the image forming apparatus to which the present invention is applied is the same as that of the first embodiment and the second embodiment, the elements having the same function or configuration as that of the first embodiment and the second embodiment Are given the same reference numerals and the detailed description is omitted. The image forming apparatus in this embodiment changes the sheet interval time according to the image to be printed. The longer the heating time in cleaning, the more effective the discharge of the contamination toner Tc. Therefore, when a halftone image is formed, the space between the sheets is expanded to make contamination toner Tc difficult to be accumulated on the heating film, and when an image other than the halftone is formed, the space between the sheets is narrow and fast. Allow throughput to be maintained.

  The method of determining the paper interval will be described in detail. FIG. 23 is a flowchart in which the image forming apparatus detects image information and determines the sheet interval extension. When the image information is received, a print signal is transmitted to the control means 31, and an image forming operation on the preceding recording material S is started (S31).

  At the same time, the acquisition unit (CPU) acquires each pixel density information of the image to be formed on the recording material S (S32), and detects whether there is any pixel whose image density is in the range of 20 to 80% (S33) . When there is no pixel whose image density is in the range of 20 to 80%, the sheet interval to the subsequent recording material S is set to the normal sheet interval. If there is a pixel whose image density is in the range of 20 to 80%, the length between sheets is set to be longer than the normal sheet length (S34, S35), and a cleaning sequence is executed between sheets at the fixing nip ( S36). It is determined whether the subsequent recording material S is the last sheet of the job (S37). If it is the last sheet, the cleaning sequence is ended (S38), and if there is a subsequent recording material, the image density information is acquired again (S32), and the image of the subsequent recording material S is obtained. Start formation. Then, at the same time, each pixel density information of the image to be formed on S is acquired, it is detected whether or not there is a pixel whose image density is in the range of 20 to 80%, and the next sheet interval time is determined.

(Experiment 7)
In the image forming apparatus according to this embodiment, the presence or absence of the occurrence of the image defect due to the cleaning sequence and the effect of the cleaning sequence were confirmed. As the image forming apparatus of the present embodiment, image forming apparatuses F and G are provided which extend the time between sheets for which the cleaning sequence is to be performed according to the image to be printed. When the image density formed on the preceding recording material is in the range of 20 to 80%, the sheet interval is extended to 450 msec in the image forming apparatus F, and the sheet interval is extended to 600 msec in the image forming apparatus G. Further, as an image forming apparatus as a comparative example to the present embodiment, an image forming apparatus H in which the sheet interval time is fixed at 300 msec of the normal time is prepared. In an environment at a temperature of 15 ° C. and a humidity of 15%, an experiment was conducted to print a total of 1000 sheets continuously using the image forming apparatuses F, G and H. The printed image T was the text pattern used in Experiment 6 and the whole-area HT pattern, and these were printed alternately.

  In the image forming apparatus G extended to the paper interval time of 600 msec, no image defect occurred even if 1000 sheets of continuous printing were performed, and the contamination toner Tc did not adhere to the surface of the heating film 16. As a result of continuously printing 1000 sheets in the image forming apparatus F extended to the paper interval time of 450 msec, although contamination toner Tc was slightly adhered to the surface of the heating film 16, no image defect occurred and no problem occurred.

  On the other hand, in the image forming apparatus H which did not extend the sheet interval as a comparative example, when 750 sheets were printed, a fixing failure was found in the fixed toner image of the printed recording material S. When the inside of the fixing device was observed, contamination toner Tc was adhered to the surface of the heating film 16. When the paper interval is expanded, contamination toner accumulation on the heating film 16 can be suppressed, and in particular, when the paper interval is longer than the outer peripheral length of the heating film 16 and the fixing roller 30, the effect is increased. By setting the sheet interval to be longer than the outer peripheral length of the heating film 16 and the fixing roller 30 which has the larger outer diameter, the contamination toner Tc for one rotation of the heating film 16 can be transferred to the fixing roller 30. Furthermore, the contamination toner Tc transferred to the fixing roller 30 can be further transferred to the pressure film 51. As a result, since the contamination toner Tc is discharged to the back of the recording material S between every sheet of paper, the contamination toner Tc hardly accumulates on the fixing film even if the number of continuous printings increases.

  As described above, according to this embodiment, it is possible to suppress the contamination toner Tc accumulation of the heating film regardless of the density of the printed image.

Example 4
Since the basic configuration of the image forming apparatus to which the present invention is applied is the same as that of the first to third embodiments, the elements having the same function or configuration as that of the first to third embodiments are described. Are given the same reference numerals and the detailed description is omitted.

  In the third embodiment, an image forming apparatus is described in which, when a halftone image (an image having pixels with an image density in the range of 20 to 80%) is formed, the sheet interval immediately after is enlarged. In the present embodiment, the following is performed so that the productivity (throughput) is not reduced even for a job with a small number of prints. That is, the number of halftone images is counted, and when the count value (count number) reaches a predetermined value (predetermined number of sheets), the paper interval time (first period) is extended to execute the extended cleaning sequence. It is

  The method of determining the paper interval will be described in detail. FIG. 24 is a flowchart in which the image forming apparatus detects image information and determines the sheet interval extension. When the image information is received, a print signal is sent to the control means 31, and an image forming operation on the preceding recording material S is started (S2401). At the same time, the acquisition unit (CPU) acquires each pixel density information of the image formed on the recording material S (S2402), and the count unit (CPU) determines whether there is a pixel whose image density is in the range of 20 to 80%. Is detected (counted) (S2403). If there is a pixel whose image density is in the range of 20 to 80%, +1 is added to the sheet number counter Yc (S2404).

  When the sheet number counter Yc is equal to or more than the threshold value Yth (S2405), the sheet interval time with the subsequent recording material S is extended to execute the cleaning sequence between sheets (S2406, S2408), and the sheet number counter Yc is set to 0 S2410). The threshold Yth is to determine whether to extend the sheet interval time. If the sheet number counter Yc is less than the threshold value Yth (S2405), a cleaning sequence between sheets is executed with the sheet interval time with the subsequent recording material S being normal (S2407, S2409). It is determined whether the subsequent recording material S is the last sheet of the job (S2411). If it is the last sheet, the cleaning sequence is ended (S2412), and if there is a subsequent recording material, density information is acquired again (S2402), and the image formation of the subsequent recording material S is performed. Start.

  If cleaning is to be performed after the last sheet of the job passes through the fixing nip portion N2, the number counter Yc is set to 0 after cleaning between sheets (S2409), and the sequence is ended (S2412). As well.

  FIG. 25 is a timing chart of the cleaning sequence when the sheet interval time is S1 when the sheet number counter Yc is equal to or more than the threshold value Yth. The start timing of the cleaning sequence is the timing when it is detected that the trailing edge of the recording material S has passed the sheet discharge sensor 41 (C2501). In the cleaning sequence, the cleaning temperature is changed to the cleaning temperature adjustment temperature (T2) higher than the temperature adjustment temperature (T1) at the time of sheet feeding, and the cleaning sequence is started. When S2 has passed since the temperature control temperature (T2) was changed to the cleaning temperature control temperature (T2), the temperature adjustment temperature during sheet feeding (image processing) is performed so that the influence of the temperature control temperature set high for cleaning The temperature is adjusted to the pre-passing temperature control temperature (T3) lower than T1). When S3 has passed since the temperature adjustment temperature (T3) before sheet passing, the temperature adjustment temperature (T1) at sheet passing is changed for the subsequent recording material S.

  When the sheet number counter Yc is less than the threshold value Yth, since the cleaning sequence is performed immediately after the halftone image without extending the inter-sheet time, contamination toner Tc may be accumulated on the heating film. Therefore, the threshold value Yth, the cleaning temperature adjustment time S2, and the cleaning temperature adjustment temperature T2 are set such that the contamination toner Tc accumulated on the heating film can be discharged to the recording material S while the number counter Yc reaches the threshold Yth. It is necessary to set it.

  As described above, according to the fourth embodiment, it is possible to simultaneously maintain the productivity and suppress the accumulation of the contamination toner Tc of the heating film.

[Example 5]
Since the basic configuration of the image forming apparatus to which the present invention is applied is the same as that of the first to fourth embodiments, it has the same function or configuration as that of the first to fourth embodiments. The same symbols are given to the elements, and the detailed description is omitted.

  Hereinafter, a cleaning sequence which is executed by extending the sheet interval is called an extended cleaning sequence, and a cleaning sequence which is executed without extending the sheet interval is called a normal cleaning sequence. The paper interval when not extending the paper interval referred to here is a normal paper interval determined by productivity (throughput).

  When receiving the image information, the video controller 300 executes the image data processing described in FIG. 21 and then transmits a print signal to the control means 31. However, image data processing may take time if the image data is large. If it takes time to process image data, the subsequent image formation can not be started in the sheet interval time determined by the control unit 31, and the subsequent image formation is performed at the timing when the print signal is transmitted from the video controller 300 to the control unit 31. Can be started.

  In the present embodiment, even when the value of the sheet number counter Yc described in the fourth embodiment does not reach the threshold value Yth, the cleaning sequence is executed as follows. That is, whether or not the extended cleaning sequence is to be performed is determined according to the time from when the trailing end of the recording material passes the discharge sensor 41 to when the leading end of the subsequent recording material reaches the fixing device F1. Hereinafter, the time of the extended cleaning sequence in the present embodiment is 5 seconds.

  In the case of full-color printing in the image forming apparatus P, the time corresponding to the distance from the position exposed by the exposure device 6 on the surface of the photosensitive drum 4Y to the discharge sensor 41 is 5.5 sec. That is, in the case of full color printing, it is possible to determine whether the sheet interval time is 5 seconds or more at the timing when the trailing edge of the recording material S passes the sheet discharge sensor 41.

  However, in the case of mono color printing, the time corresponding to the distance from the position exposed by the exposure device 6 on the surface of the photosensitive drum 4K to the sheet discharge sensor 41 is 3.5 seconds. That is, in the case of mono-color printing, it can not be determined whether the sheet interval time will be 5 seconds or more at the timing when the trailing edge of the recording material S passes the sheet discharge sensor 41.

  FIG. 26 is a flowchart for determining the cleaning sequence to be executed at the sheet interval timing. When the image information is received, a print signal is transmitted to the control means 31, and an image forming operation on the preceding recording material S is started (S2601). At the same time, each pixel density information of the image to be formed on the recording material S is acquired (S2602), and it is detected whether there is any pixel whose image density is in the range of 20 to 80% (S2603). If there is a pixel whose image density is in the range of 20 to 80%, +1 is added to the sheet number counter Yc (S2604).

  When the sheet number counter Yc is equal to or more than the threshold value Yth (S2605), the inter-sheet time with the subsequent recording material S is extended (S2606), and when the inter-sheet cleaning start timing comes (S2608), the extended cleaning sequence is executed S2612). Then, the number counter Yc is set to 0 (S2613).

  If the sheet number counter Yc is less than the threshold value Yth (S2605), the sheet interval time with the subsequent recording material S is kept normal (S2607), and when the sheet interval cleaning start timing comes (S2609), full color printing is confirmed (S2605) S2610). In the case of full-color printing, it is checked whether the subsequent image formation has not started (S2610). If the subsequent image formation has not started, the extended cleaning sequence is executed (S2612) and the sheet counter Yc is set to 0. (S2613). In the case of mono-color printing or in the case of full-color printing and when the subsequent image formation is started, the normal cleaning sequence is executed (S2614).

  It is determined whether the subsequent recording material S is the last sheet of the job (S2615). If it is the last sheet, the cleaning sequence is ended (S2616), and if there is a subsequent recording material, image density information is acquired again (S2602), and the image formation of the subsequent recording material S is started.

  As described above, according to this embodiment, the extended cleaning sequence can be executed while suppressing the decrease in productivity.

  In the present embodiment, although the image data processing of the video controller 300 is taken as an example as a factor for delaying the image formation, the present invention is not limited to this.

[Example 6]
The basic configuration of the image forming apparatus to which the present invention is applied is the same as that of the first to fifth embodiments, and therefore, an element having the same function or configuration as that of the first to fifth embodiments. Are given the same reference numerals and the detailed description is omitted.

  In the fifth embodiment, even in the case where the value of the number counter Yc does not reach the threshold Yth, the cleaning sequence is executed in the following case. That is, the extended cleaning sequence is executed when the image data processing notice time received from the video controller 300 is equal to or longer than the predetermined time. The time of the extended cleaning sequence in this embodiment is 5 seconds as in the fifth embodiment.

  FIG. 27 is a timing chart when the image forming apparatus executes image formation for three sheets using the image data processing advance notice time. The video controller 300 receives the first image information, notifies the control means 31 of the time Tp1 required for the first image data processing as the image data processing advance notice time (C2701), and completes the image data processing. A print signal is transmitted (C2702). When receiving the print signal, the control means 31 starts image formation (C2702). The video controller 300 receives the image information of the second image, notifies the time Tp2 necessary for the image data processing of the second image as the image data processing advance notice time to the control means 31 (C2703), and completes the image data processing. The print signal is transmitted (C2705). When the image formation for the first sheet is completed (C2704), the control means 31 starts the image formation for the second sheet after the normal sheet interval time Tk has elapsed (C2706). Although the second print signal is received (C2705), image formation is not started until the normal inter-paper time Tk has elapsed. The video controller 300 receives the third image information, notifies the control means 31 of the time Tp3 required for the third image data processing as the image data processing advance notice time (C2707), and completes the image data processing. The print signal is transmitted (C2710). The control means 31 completes the formation of the second image (C2708), and when the normal sheet interval time Tk has elapsed (C2709), prepares for the formation of the third image in accordance with the image data processing notice time. Do. Then, after the image data processing notice time has elapsed and the print signal is received from the video controller 300, formation of a third image is started (C2710).

  As described above, the control means 31 can know in advance the timing to start the image formation by the image data processing advance notice time.

  FIG. 28 is a flowchart for determining the cleaning sequence to be executed at the sheet interval timing. When image information is received, a print signal is sent to the control means 31, and an image forming operation on the preceding recording material S is started (S2801). At the same time, each pixel density information of the image to be formed on the recording material S is acquired (S2802), and it is detected whether there is a pixel whose image density is in the range of 20 to 80% (S2803). If there is a pixel whose image density is in the range of 20 to 80%, +1 is added to the sheet number counter Yc (S2804). When the sheet number counter Yc is equal to or more than the threshold value Yth (S2805), the sheet interval time with the subsequent recording material S is extended (S2806). Then, when the inter-paper cleaning start timing comes (S2808), the extended cleaning sequence is executed (S2812), and the sheet number counter Yc is set to 0 (S2813).

  When the sheet number counter Yc is less than the threshold value Yth (S2805), the inter-sheet time with the subsequent recording material S is kept normal (S2807), and when the inter-sheet cleaning start timing comes (S2809), the subsequent image data processing notice It is confirmed whether the time is 5 seconds or more (S2810). If the subsequent image data processing notice time is 5 seconds or more, the extended cleaning sequence is executed (S2812), and the sheet number counter Yc is set to 0 (S2813). If the subsequent image data processing notice time is less than 5 seconds, the normal cleaning sequence is executed (S2811). It is determined whether the subsequent recording material S is the last sheet of the job (S2814). If it is the last sheet, the cleaning sequence is ended (S2815), and if there is a subsequent recording material, image density information is acquired again (S2802), and image formation of the subsequent recording material S is performed. Start.

  As described above, according to this embodiment, the extended cleaning sequence can be performed while suppressing the decrease in productivity.

[Example 7]
Since the basic configuration of the image forming apparatus to which the present invention is applied is the same as that of the first to sixth embodiments, the elements having the same function or configuration as that of the first to sixth embodiments are described. Are given the same reference numerals and the detailed description is omitted.

  In this embodiment, an image forming apparatus having a plurality of extended cleaning sequences that can be executed according to the image data processing advance notice time will be described. In this embodiment, an embodiment having three extended cleaning sequences of extended cleaning 1 to 3 will be described. Table 3 shows the details of the extended cleaning sequences 1 to 3.

  The extended cleaning sequence 1 is a sequence that is executed when the sheet number counter Yc becomes equal to or more than the threshold value Yth. In the extended cleaning sequence 2, the sheet interval time and temperature adjustment time are shorter than in the extended cleaning sequence 1, and the amount of contamination toner Tc that can be discharged is also smaller than in the extended cleaning sequence 1. In the present embodiment, the sheet number counter Yc is set to a half value. In the extended cleaning sequence 3, the sheet interval time and the temperature adjustment time are shorter than in the extended cleaning sequence 2, and the cleaning temperature adjustment temperature is also low. In the present embodiment, the number counter Yc is decremented by one.

  FIG. 29 is a flowchart for determining the cleaning sequence to be executed at the sheet interval timing. When the image information is received, a print signal is sent to the control means 31, and an image forming operation on the preceding recording material S is started (S2901). At the same time, each pixel density information of the image to be formed on the recording material S is acquired (S2902), and it is detected whether there is any pixel whose image density is in the range of 20 to 80% (S2903). If there is a pixel whose image density is in the range of 20 to 80%, +1 is added to the sheet number counter Yc (S2904).

  When the sheet number counter Yc is equal to or more than the threshold value Yth (S2905), the inter-sheet time with the subsequent recording material S is extended (S2906), and the inter-sheet cleaning start timing (S2908) executes extended cleaning sequence 1 (S2911) . Thereafter, the number counter Yc is set to 0 (S2912).

  If the sheet number counter Yc is less than the threshold value Yth (S2905), the sheet interval time with the subsequent recording material S is set to the normal sheet interval (S2907). Then, at the start timing of the inter-sheet cleaning (S2909), the subsequent image data processing notice time is confirmed (S2910, S2913, S2916). If the subsequent image data processing notice time is 5 seconds or more, the extended cleaning sequence 1 is executed (S2911), and the sheet number counter Yc is set to 0 (S2912). If the subsequent image data processing notice time is 3 seconds or more and less than 5 seconds, the extended cleaning sequence 2 is executed (S2914), and the sheet number counter is halved (S2915). When the subsequent image data processing notice time is 1 sec or more and less than 3 sec, the extended cleaning sequence 3 is executed (S2917), and the number counter is decremented by 1 (S2918). If the subsequent image data processing notification time is less than 1 sec, or if the subsequent image data processing notification time has not been received, a normal cleaning sequence is executed (S2919).

  Then, it is determined whether the subsequent recording material S is the last sheet of the job (S2920). If it is the last sheet, the cleaning sequence is ended (S2921), and if there is a subsequent recording material, the image density information is acquired again (S2902), and the image formation of the subsequent recording material S is started.

  As described above, according to this embodiment, the extended cleaning sequence can be performed while suppressing the decrease in productivity.

  In this embodiment, although the number of extended cleaning sequences included in the image forming apparatus is three, and the temperature adjustment time, temperature adjustment temperature, and sheet counter calculation are values shown in Table 3, the configuration of the fixing device F1 is used. It is a change, not limited to this.

Claims (4)

An image forming unit that forms a toner image on a recording material;
A roller, a heating member in contact with the roller to heat the roller, and a backup member in contact with a position different from the heating member of the roller in the rotational direction of the roller to form a nip portion; A fixing unit which heats while conveying the recording material on which the toner image is formed in the nip portion and fixes the toner image on the recording material;
A temperature detection unit that detects the temperature of the heating member;
A control unit configured to control power supplied to the heating member such that a temperature detected by the temperature detection unit becomes a target temperature;
In an image forming apparatus comprising
When a plurality of recording materials are continuously fixed, the control unit sets the target in at least a part of the first period of the interval in which the nip portion is an interval between the preceding recording material and the subsequent recording material. An image forming apparatus, wherein the temperature is made higher than the target temperature in a second period in which the recording material is conveyed in the nip portion. An acquisition unit for acquiring density information from image data;
When the density of the toner image formed on the recording material is within a predetermined density range, the length of the first period immediately after that is made longer than that when the density is outside the predetermined density range. An image forming apparatus according to claim 1. An acquisition unit that acquires density information from image data;
A counting unit for counting the number of recording materials on which the toner image is formed within a predetermined density range;
2. The image forming method according to claim 1, wherein each time the count number of the counting section reaches a predetermined number, the length of the first period immediately after that is made longer than the case where the predetermined number is not reached. apparatus.   The heating member has a cylindrical film and a heater in contact with the inner surface of the film, and the heater forms a pressure contact portion with the roller via the film. The image forming apparatus according to any one of 3.

Images