JP2010181728A - Image forming apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve the following problem: in order to stabilize a fixing process of a fixing device, an electrophotographic image forming apparatus maintains constant fixability by changing the speed of paper passage in accordance with the paper thickness of a printing medium, however, the thicker the printing medium is, it is necessary to lower the speed at which the printing medium is passed, which results in a decrease in printing speed. <P>SOLUTION: The image forming apparatus includes: heating sections (30, 33, 350, and 2a) that heat recording paper 50 with a toner image 58 transferred thereto; a pressure applying section (32) that forms a predetermined nip portion 60 by applying pressure to the heating sections; a conveying drive means for driving at least the heating sections or the pressure applying section in order to convey the recording paper 50 at a predetermined conveying speed in a predetermined direction via the nip portion; and a pressure quantity control means (34, 35, 37, 36, 28, 27, and 42b) that control an amount of pressure applied by the pressure applying section. In accordance with the type of the recording paper 50, the pressure quantity control means controls the quantity of pressure applied by the pressure applying section. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to an image forming apparatus including a fixing device used in an image forming apparatus using an electrophotographic system such as a printer, a copier, a facsimile machine, and a multifunction machine.

  Conventionally, in an image forming apparatus such as a printer, a copier, a facsimile machine, or a multi-function machine that employs the above-described electrophotographic method, the surface of the photosensitive drum is uniformly charged by a charging unit and then exposed by an exposure unit such as an LED head. The surface of the body drum is exposed to form an electrostatic latent image corresponding to the image information, and a toner image is formed by electrostatically attaching the toner thinned on the developing roller to the electrostatic latent image. . Then, the toner image formed on the photosensitive drum is transferred onto a printing medium fed from a paper feeding device. Thereafter, in the fixing device, the toner image is fixed by applying heat and pressure to the print medium onto which the toner image has been transferred, and an image is formed on the print medium.

  The fixing device heats and adds the unfixed toner image when the print medium onto which the toner image has been transferred passes through the nip formed between the fixing roller and the pressure roller pressed against the fixing roller. It is configured to be pressed and fixed on the print medium (see, for example, Patent Document 1). In such a conventional fixing device, since the nip width is constant, for example, according to the thickness of the print medium passing through the nib portion, the passage time of the print medium is changed to control the passage time at the nip portion. Thus, the fixing property is kept constant.

Japanese Patent Laying-Open No. 2004-361839 (paragraphs 0021 to 0023, FIG. 2)

  However, in the conventional fixing device, there is a problem that it is necessary to slow down the passage speed of the print medium as the print medium becomes thicker, which causes a decrease in the print speed.

An image forming apparatus according to the present invention is an image forming apparatus provided with a fixing device that fixes a developer attached to a print medium by applying heat and pressure,
A heating unit that heats the printing medium, a pressurizing unit that pressurizes the heating unit to form a predetermined nip portion by the heating unit, and the printing medium is predetermined in a predetermined direction via the nip portion. Transporting means for driving at least one of the heating unit and the pressurizing unit, and a pressurizing amount control unit for controlling the pressurizing amount by the pressurizing unit,
The pressurization amount control means controls the pressurization amount by the pressurizing unit according to the type of the print medium.

  According to the present invention, the amount of pressurization by the pressurization unit is controlled in accordance with the type of print medium so as to obtain a good fixing state, thereby suppressing a decrease in print processing speed due to a decrease in transport speed. Can do.

1 is a schematic configuration diagram for explaining a main configuration of an image forming apparatus according to a first embodiment of the present invention. FIG. 2 is a main part configuration diagram of the fixing device according to the first embodiment. FIG. 3 is a diagram illustrating a configuration of a main part of a load variable mechanism of the fixing device when the fixing device is viewed from an arrow A direction that is a conveyance direction of the recording paper illustrated in FIG. FIG. 6 is a diagram for explaining a cam position of a fixing device. 2 is a block diagram illustrating a configuration of a main part of a control system of the fixing device provided in the image forming apparatus according to the present invention. FIG. 3 is a flowchart illustrating a flow of a printing process performed by the image forming apparatus in the first embodiment. 6 is a graph showing the relationship between the compression rate of the heat-resistant elastic layer of the fixing roller of the fixing device and the durable sheet passing number in the second embodiment. 9 is a graph showing the relationship between the compression rate (%), nip width (mm), and sheet feeding speed (PPM) of the heat resistant elastic layer of the fixing roller of the fixing device in the second embodiment. 10 is a flowchart illustrating a flow of a printing process performed by the image forming apparatus in the second embodiment. FIG. 9 is a main part configuration diagram showing a main part configuration of a fixing device employed in an image forming apparatus according to a third embodiment of the present invention. It is a disassembled perspective view which shows the structural example of a planar heating element. 10 is a graph showing the relationship between the compression rate of the foamed silicone rubber (elastic) layer of the fixing roller of the fixing device and the durable sheet passing number in the third embodiment.

Embodiment 1 FIG.
FIG. 1 is a schematic configuration diagram for explaining a main configuration of the image forming apparatus according to the first embodiment of the present invention.

  The image forming apparatus 1 has a configuration as a color electrophotographic printer capable of printing four colors of black (K), yellow (Y), magenta (M), and cyan (C). As shown in the figure, the image forming apparatus 1 includes a black (K) image forming unit 11K and a yellow (Y) image forming unit along a conveyance path of a recording sheet 50 as a printing medium. 11Y, an image forming unit 11M for magenta (M), and an image forming unit 11C for cyan (C) (may be referred to as an image forming unit 11 when it is not necessary to distinguish). These four image forming units 11 are detachable from the main body of the image forming apparatus 1, and for this purpose, the upper cover 17 of the image forming apparatus 1 is provided so as to be opened and closed.

  Each of the image forming units 11K, 11Y, 11M, and 11C corresponds to an exposure device 16K, 16Y, 16M, and 16C supported by the upper cover 17 (may be referred to as the exposure device 16 if it is not necessary to distinguish). Are arranged. These four image forming units 11 have the same configuration except for toner as a developer to be used. Accordingly, here, the internal configuration of the black (K) image forming unit 11K will be described as an example.

  The image forming unit 11K forms the electrostatic latent image on the surface of the photosensitive drum 12K that uniformly charges the surface of the photosensitive drum 12K that uniformly charges the surface of the photosensitive drum 12K that uniformly charges the surface of the photosensitive drum 12K that carries the toner image. An exposure device 16K composed of an LED array, a developing roller 102 that forms a toner image on an electrostatic latent image by frictional charging, a toner supply unit 103 that supplies toner to the developing roller 102, and a residual that remains on the surface of the photosensitive drum 12K after transfer A cleaning blade 104 that scrapes off the toner is provided.

  Each of the photosensitive drums 12K, 12Y, 12M, and 12C of the four image forming units 11 (may be referred to as the photosensitive drum 12 when there is no need to distinguish them) is provided with a transfer roller 13K, 13Y, 13M, and 13C (may be referred to as photosensitive drum 13 when there is no need to distinguish) are arranged so as to be in pressure contact with each other. The conveyor belt 14 is stretched and driven by a drive roller 55 and an idle roller 56 to convey the recording paper 50 in the conveyance direction indicated by the arrow A. While the recording paper 50 is conveyed by the conveying belt 14 in the direction of arrow A, the toner images of the respective colors formed on the photosensitive drums 12K, 12Y, 12M, 12C are transferred to the opposing transfer rollers 13K, 13Y, 13M, The images are sequentially transferred onto the recording paper 50 by 13C.

  The fixing device 3 is disposed at the subsequent stage of the image forming unit 11C. The fixing device 3 receives the recording paper 50 onto which the toner image has been transferred, fixes the toner image on the recording paper 50 by applying pressure and heat as will be described later, and then discharges the recording paper 50. The fixing device 3 will be described in detail later.

  The paper feed cassette 18 is disposed below the image forming apparatus 1 and accommodates the recording paper 50. A paper feed mechanism is disposed adjacent to the front end of the paper feed cassette 18. The paper feed mechanism includes paper feed rollers 19a and 19b and a separation side 20, and separates and feeds the recording paper 50 one by one. The fed recording paper 50 passes through the paper sensor 51 and is sent to the conveying roller pair 21. The conveyance roller pair 21 is rotated by a driving unit (not shown) from the time when the recording paper 50 passes through the paper sensor 51 and feeds the recording paper 50 without stopping.

  The recording paper 50 sent out by the transport roller pair 21 passes through the paper sensor 52 and is sent to the registration roller pair 22. The registration roller pair 22 is started to rotate by a drive unit (not shown) at a timing delayed by a predetermined time from the time when the recording paper 50 passes the paper sensor 52. Therefore, the recording paper 50 is pushed into the pressure contact portion of the registration roller pair 22 in a slightly bent state, and the skew is corrected. The recording paper 50 sent out from the registration roller pair 22 passes through the writing sensor 53 and is sent to the conveying belt 14. A series of image forming operations by the image forming unit 11 and the like are performed in synchronization with the detection timing of the writing sensor 53.

  On the other hand, the recording paper 50 discharged by the fixing device 3 passes through the paper sensor 54, is conveyed by the discharge roller pair 23, and is further discharged onto the upper cover 17 by the discharge conveyance roller pair 24. The discharge roller pair 23 and the discharge conveyance roller pair 24 are rotated by a driving unit (not shown) from the time when the recording paper 50 passes the paper sensor 54, and send out the recording paper 50 without stopping.

Next, the fixing device 3 will be further described.
FIG. 2 is a main part configuration diagram of the fixing device 3 in the present embodiment, FIG. 3 is a main part configuration diagram showing a load variable mechanism of the fixing device 3, and FIG. It is a figure with which it uses for description of a position.

  As shown in FIG. 2, in the fixing device 3, a nip portion 60 having a nip width N for fixing an unfixed toner image 58 onto a recording paper 50 brings the fixing roller 30 and the pressure roller 32 into pressure contact with each other. Is formed. The fixing roller 30 is a hollow roller having an outer diameter of 25 mm, and a 1.3 mm thick heat-resistant elastic layer 302 made of silica rubber is formed on the outer peripheral surface 301 made of aluminum, and the outer peripheral surface has a thickness as a release layer. A 0.03 mm fluororesin layer 303 is formed. Here, aluminum is used for the core metal, but other metals such as iron may be used. The pressure roller 32 is a solid roller having an outer diameter of 24 mm. A heat-resistant elastic layer 322 made of foamed silicone rubber is formed on a steel cored bar outer peripheral surface 321, and a release layer is formed on the outer peripheral surface. A fluororesin layer 323 having a thickness of 0.03 mm is formed.

  A thermistor is provided as a temperature sensor 350 near the surface of the fixing roller 30, and a halogen heater 33 is provided as a heat source inside the fixing roller 30. The heat source is not limited to a halogen heater, and induction heating or the like can be used.

  FIG. 3 shows a main configuration of the load variable mechanism of the fixing device 3 when the fixing device 3 is viewed from the direction of arrow A which is the conveyance direction of the recording paper 50 shown in FIG.

  As shown in the figure, the fixing roller 30 is rotatably held at its left and right ends by cores 39 and 39, and is transmitted from a driving motor (not shown) to a driving gear 31 disposed at one end. It receives the driving force and rotates in the direction of arrow B. Further, a halogen heater 33 as a heat source is provided on the rotation axis inside the hollow metal core.

  On the other hand, at the left and right ends of the core of the pressure roller 32, bearings 34 and 34 and springs 35 and 35 for pressing the pressure roller 32 toward the fixing roller 30 via the bearings 34 and 34 are disposed. The At this time, the bearings 34 and 34 are guided by guide means (not shown) so that the rotation shaft of the pressure roller 32 can move in parallel in a direction approaching or separating from the rotation shaft of the fixing roller 30. The bearings 34 and 34 may be configured by enclosing a resin molded product or a ball bearing therein.

  The eccentric cams 36 and 36 for changing the spring pressure are fitted into the drive shaft 38. As shown in FIG. 2, the pressurizing springs 35 and 35 are pressed by the eccentric cams 36 and 36 via spring receiving members 37 and 37 in which rotating shafts 37a and 37a at one end are rotatably held. Has been. The drive shaft 38 is arranged in a direction parallel to the pressure roller 32. The drive shaft 38 rotates as the motor 27 is driven. The motor 27 is a pulse motor that can perform rotation control such as a rotation direction and a rotation angle by inputting a pulse, and power transmission from the motor 27 to the driving shaft 38 is performed using a gear train (not shown).

  Therefore, according to the above configuration, by changing the rotational position of the eccentric cam 36, the spring pressure applied to the bearings 34, 34 can be changed, and the pressure applied by the pressure roller 32 to the fixing roller 30 can be changed. it can. The determination of the applied pressure is performed by taking in the rotational positions of the eccentric cams 36 and 36 by the cam position reading sensor 28.

  In the present embodiment, the cam shapes of the eccentric cams 36 and 36 are determined so that the load setting of the pressure roller 32 is in three stages. FIG. 4 shows the rotational position of the eccentric cam 36 in which the load setting changes in three stages depending on the rotational position. FIG. 4A shows that the load F on one side for pressing the pressure roller 32 is set to the low load F1. The rotational position of the eccentric cam 36, the spring receiving member 37, the pressure spring 35, and the nip width N1 of the nip portion 60 are shown. FIG. Each state of the rotational position of the eccentric cam 36, the spring receiving member 37, the pressure spring 35, and the nip width N2 of the nip portion 60 when the load F on one side is set to the medium load F2 is shown in FIG. Similarly, the rotational position of the eccentric cam 36, the spring receiving member 37, the pressure spring 35, and the nip width N3 of the nip portion 60 when the load F on one side that pressurizes the pressure roller 32 is set to the high load F3. Each state is shown.

  Here, the pressure spring 35 and the eccentric cam 36 are configured so that the low load F1 = 10 kgf, the medium load F2 = 12 kgf, and the high load F3 = 16 kgf, and each is thin paper (0.07 mm or more and less than 0.1 mm). For medium thick paper (0.1 mm or more and less than 0.16 mm), and for thick paper (0.16 mm to 0.25 mm), corresponding to the paper thickness of the recording paper 50. Therefore, hereinafter, the state of FIG. 4A is sometimes referred to as a thin paper mode, the state of FIG. 4B is referred to as a medium thick paper mode, and the state of FIG.

  FIG. 5 is a block diagram illustrating a main configuration of a control system of the fixing device 3 provided in the image forming apparatus 1.

  This control system includes a control unit 26 that controls the overall operation of the image forming apparatus 1, a paper thickness reading sensor 25 disposed at the position of the registration roller pair 22 (see FIG. 1) in the conveyance path of the recording paper 50, an eccentricity, and the like. A pressure cam position sensor 28 disposed in the vicinity of the cam 36 (see FIG. 2), a printing speed control unit 41 for controlling the printing speed, and a fixing temperature of the fixing roller 30 of the fixing device 3 based on instructions from the control unit 26. A fixing control unit 42 having a temperature control unit 42a for controlling the rotation and a pressurizing amount control unit 42b for controlling the rotational position of the eccentric cam 36, and a print data receiving unit 43 for receiving a print data signal from an external device. Prepare.

  The printing speed control unit 41 that controls the printing speed includes, for example, a driving motor (not shown) for each image forming unit 11, a driving motor (not shown) for the fixing device 3, and a drive roller that conveys the conveyance belt 14. A motor (not shown) for driving 55, a conveyance motor (not shown) for driving each roller pair, and the like are driven and controlled in synchronization to set a predetermined printing speed. Note that the printing speed here is a conveyance speed when the recording paper 50 passes through each image forming unit 11 and the fixing device 3, and is hereinafter referred to as a paper passing speed Vp.

  The temperature control unit 42 a of the fixing control unit 42 monitors the temperature of the fixing roller 30 by a temperature sensor 350 disposed near the surface of the fixing roller 30 (see FIG. 2), and a halogen installed inside the fixing roller 30. The heater 33 is turned on / off to keep the surface temperature of the fixing roller 30 at a predetermined temperature instructed by the control unit 26, and the pressurizing amount control unit 42 b of the fixing control unit 42 is based on an instruction from the control unit 26. The rotation of the cam motor 27 that rotationally drives the eccentric cam 36 is controlled until the rotational position of the eccentric cam 36 (see FIG. 2) reaches a desired position.

  Therefore, the control unit 26 inputs the paper thickness information from the paper thickness reading sensor 25 that measures (detects) the thickness of the recording paper 50, and the thickness of the recording paper 50 to be printed is the above-described three levels, that is, It is determined whether it belongs to thick paper, medium thick paper, or thin paper, and the pressure cam position sensor 28 is monitored so that the eccentric cam 36 is at a rotational position corresponding to the determined paper thickness, and this rotational position is reached. Until the cam motor 27 is rotated.

  As shown in FIG. 2, the fixing device 3 configured as described above receives the recording paper 50 onto which the toner image 58 has been transferred, and pressurizes and heats the recording paper 50 at the nip portion 60 to record the toner image on the recording paper. Fix to 50.

  The fixing roller 30, the halogen heater 33, the temperature sensor 350, the temperature control unit 42a, and the like correspond to a heating unit, the pressure roller 32 corresponds to a pressing unit, and a bearing 34, a spring 35, a spring receiving member 37, a biasing unit, and the like. The lead cam 36, the pressurization cam position sensor 28, the cam motor 27, and the pressurization amount control unit 42b correspond to the pressurization amount control means.

  Next, a description will be given of print tests performed in print modes corresponding to print sheets having different paper thicknesses and the results thereof.

The fixing test was performed under the following conditions.
(1) As the test apparatus, the image forming apparatus having the above-described configuration including the fixing device that can be set in the thin paper mode, the medium thick paper mode, and the thick paper mode is used.
(2) The toner density (each color single color) of the end-fixed recording paper was set to 100% printing duty.
(3) The fixing temperature of the fixing device was set in five stages at intervals of 10 ° C. in the range of 140 to 180 ° C.
(4) The printing paper conveyance speed (paper feeding speed Vp) was set to 70 mm / sec.
(5) Fuji Xerox Co., Ltd. P paper A4 (64 g / m ² , thickness of about 0.07 mm) as a thin paper, Oki Data Co., Ltd. Excellent White A4 thick mouth (105 g / m ² , thickness) as a medium cardboard About 0.13 mm) and Mondi (160 g / m ² , thickness about 0.19 mm) were used as cardboard.

  Table 1 shows the results of the fixing test. In the table, the evaluation marks “x”, “Δ”, and “◯” indicate that the toner image after the fixing process has a large peeling. “X” is indicated as an evaluation result, “Δ” is indicated when there is a minute peeling, and “◯” is indicated when there is no peeling.

  As is apparent from the table, in Test 1 in which the fixing device is set to the thin paper mode using the above thin paper, the load on one side is low load F1 = 10 kgf, the nip width N1 = 4 mm, and the fixing temperature is in the range of 140 to 180 ° C. Good fixability could be obtained. Further, in Test 2 in which the above-described medium thick paper is used and the fixing device is set to the medium thick paper mode, the one-side load is medium load F2 = 12 kgf, the nip width N2 = 5 mm, and good fixing is performed in the fixing temperature range of 160 to 180 ° C. I was able to get sex. Furthermore, in Test 3 in which the fixing device is set to the thick paper mode using the above-mentioned thick paper, the one-side load is high load F3 = 16 kgf, the nip width N3 = 6 mm, and good fixability in a fixing temperature range of 170 to 180 ° C. I was able to get.

  As shown in the above test results, the fixing temperature is set within a predetermined temperature range (170 to 180 ° C. in this case), and the fixing temperature is appropriately changed by changing the load F for pressing the pressure roller 32 according to the paper thickness. Is fixed, and even when the sheet passing speed Vp is constant (70 mm / sec in this case), the toner image can be satisfactorily fixed on the recording sheets of thin paper, medium thick paper, and thick paper.

  FIG. 6 is a flowchart showing the flow of printing processing performed by the image forming apparatus 1 that employs the fixing device 3, which is performed based on the test results described above. Based on this flowchart, the printing operation by the image forming apparatus 1 will be described below with reference to FIGS.

  First, in order to initialize the load F to the pressure roller 32 prior to the printing operation performed by receiving the print data from the external device received by the print data receiving unit 43 (FIG. 5), the low load F1 (for thin paper) ), The eccentric cam 36 is rotated by the motor 27, and the eccentric cam 36 is set to the thin paper mode shown in FIG. 4A (step S101).

  When the image forming operation is started, the recording paper 50 accommodated in the paper feeding cassette 18 is separated and fed out one by one by the paper feeding rollers 19a and 19b and the separating piece 20, and is conveyed to the registration roller 22 by the conveying roller 21. (Step S102). Here, the paper thickness reading sensor 25 detects a change in roller position when the recording paper 50 passes through the registration roller 22 to detect the paper thickness, and transmits the detected paper thickness information to the control unit 26. The thickness information is captured by the control unit 26 (step S103). In this state, the conveyance of the recording paper 50 is temporarily stopped. The following steps S104 to S111 are executed during the conveyance pause period.

  That is, first, it is determined whether or not the recording paper 50 detected here is a thin paper (step S104). If it is determined that the recording paper 50 is thin (paper thickness is 0.07 mm or more and less than 0.1 mm) (Yes in step S104), the output of the cam position sensor 28 is taken in, and the eccentric cam 36 is shown in FIG. ) To determine whether it is in the thin paper mode position (step S105). If the eccentric cam 36 is in the thin paper mode position (Yes in step S105), the process proceeds to step S112 as it is. If the eccentric cam 36 is not in the thin paper mode position (step S105, No), a change process to the thin paper mode is performed. (Step S106), and then the process proceeds to Step S112.

  On the other hand, when it is determined in step S104 that the recording paper 50 is not a thin paper (No in step S104), it is further determined whether or not the recording paper 50 detected here is a medium thick paper (step S107). If it is determined that the recording paper 50 is medium-thick paper (paper thickness is 0.1 mm or more and less than 0.16 mm) (step S107, Yes), the output of the cam position sensor 28 is taken in, and the eccentric cam 36 is shown in FIG. It is confirmed whether or not it is in the middle thick paper mode position shown in b) (step S108). If the eccentric cam 36 is in the middle cardboard mode position (step S108, Yes), the process proceeds to step S112, and if it is not in the middle cardboard mode position (step S108, No), the mode is changed to the middle cardboard mode. Processing is performed (step S109), and then the process proceeds to step S112.

  Further, when it is determined in step S107 that the recording paper 50 is not a medium thick paper (No in step S107), it is determined that the recording paper 50 detected here is a thick paper (paper thickness is 0.16 mm to 0.25 mm). Then, the output of the cam position sensor 28 is taken in, and it is confirmed whether or not the eccentric cam 36 is in the thick paper mode position shown in FIG. 4C (step S110). If the eccentric cam 36 is in the thick paper mode position (step S110, Yes), the process proceeds to step S112 as it is. If the eccentric cam 36 is not in the thick paper mode position (step S110, No), a change process to the thick paper mode is performed. (Step S111), and then the process proceeds to Step S112.

  After the load F of the pressure roller 32 is set in the processes of steps S104 to S111, the conveyance of the printing paper 50 by the registration roller 22 is resumed, and the electrophotographic process (charging, exposure, development, transfer, fixing) An image forming operation based on the above is performed (step S112).

  Thereafter, it is confirmed whether or not there is a page to be imaged next (step S113). If there is an unprocessed page (step S113, Yes), the process returns to step S102 and the processes of steps S102 to S112 are performed. If no unprocessed pages remain (step S113, No), the output of the cam position sensor 28 is taken in order to reinitialize the load F on the pressure roller 32, and the eccentric cam 36 is shown in FIG. ) To determine whether it is in the thin paper mode position (step S114). If the eccentric cam 36 is in the thin paper mode position (step S114, Yes), the image forming process is terminated as it is. If the eccentric cam 36 is not in the thin paper mode position (step S114, No), the process is changed to the thin paper mode. (Step S115), and then the image forming process is terminated. Accordingly, the setting operation of the load F of the pressure roller 32 and the image forming operation are executed for each recording sheet until there is no print data.

  Therefore, according to this flow, the printing paper transport speed (paper passing speed Vp) is set to 70 mm / sec and the fixing temperature is set to a predetermined value within a predetermined temperature range (170 to 180 ° C. in this case). The load F applied to the pressure roller 32 is appropriately set according to the paper thickness of the recording paper to be formed, and a necessary nip width N is formed. For this reason, a good fixing state can be maintained regardless of the thickness of the recording paper used.

  As described above, according to the image forming apparatus of the present embodiment, even when the recording paper is thick, a good fixing state can be maintained without reducing the recording paper conveyance speed. There will be no decline.

Embodiment 2. FIG.
The image forming apparatus according to the present embodiment is configured to appropriately change the load F for pressing the pressure roller 32 or the sheet passing speed Vp according to the thickness of the recording paper 50 to be used. . Therefore, the difference between the image forming apparatus of the present embodiment and the image forming apparatus of the first embodiment is that the speed control unit 41 shown in FIG. 1 is different from the first sheet passing speed Vp1 and the second sheet passing speed Vp2 that is slower than the first sheet passing speed, and the processing content of the control unit 26 is partially different. Accordingly, in view of the above differences, FIGS. 1 to 5 are referred to as they are as necessary.

  Here, the relationship between the compression rate of the heat-resistant elastic layer 302 of the fixing roller 30 of the fixing device 3 and the durable sheet passing number will be described. FIG. 7 is a graph showing the relationship between the compression rate of the heat-resistant elastic layer 302 of the fixing roller 30 of the fixing device 3 and the durable sheet passing number.

  In the graph of the figure, the compression force of the heat-resistant elastic layer 302 of the fixing roller 30 is adjusted to various values (8, 13, 14, 15, 16, 17, 18 (%)) by adjusting the pressure applied by the pressure roller 32. A fixing durability test is performed using the fixing device, and the total number of recording sheets when a visible printing defect occurs in the fixed toner image due to durability deterioration of the heat-resistant elastic layer 302, that is, rubber deterioration (softening, curing, etc.). The number of sheets is plotted as the number of durable sheets. In this example, a medium-thick recording paper is used and continuous paper feeding is performed at a 5% print duty, the paper feeding speed is 12 PPM, and the fixing temperature is set in a range of 170 ° C. to 180 ° C. The compression rate of the heat-resistant elastic layer 302 here is the ratio of the compression width of the maximum compression portion in the nip portion 60 (FIG. 2) to the layer thickness of the heat-resistant elastic layer 302. In FIG. 2, it is not depicted that the compression is clearly generated in the nip portion 60, but it is assumed that the compression is actually generated.

  As shown in the graph of FIG. 7, when the printing speed is set to 12 PPM, when the vicinity of each plotted point is connected by a plurality of straight lines, the intersection of the straight lines with different inclinations, that is, the changing point is in the vicinity of a compression ratio of 14%. It can be seen that when the compression ratio exceeds 14, the number of durable sheets is remarkably reduced. For this reason, it is understood that the durability of the fixing device can be improved by performing the fixing operation in a region where the compression ratio is 14% or less.

  Next, a description will be given of printing tests and results obtained by variously setting the load F for pressing the pressure roller 32 or the sheet passing speed Vp of the recording paper with respect to printing paper having different paper thicknesses.

The fixing test was performed under the following conditions.
(1) As a test apparatus, the above-described fixing device that can be set to the thin paper mode, the medium thick paper mode, and the thick paper mode is provided, and an image forming apparatus that can further set the paper passing speed to Vp1 = 70 mm / s and Vp2 = 59 mm / s. Was used.
(2) The toner density (each color single color) of the end-fixed recording paper was set to 100% printing duty.
(3) The fixing temperature of the fixing device was set in five stages at intervals of 10 ° C. in the range of 140 to 180 ° C.
(4) Fuji Xerox Co., Ltd. P paper A4 (64 g / m ² , thickness of about 0.07 mm) as thin paper, Oki Data Co., Ltd. Excellent White A4 thick mouth (105 g / m ² , thickness) as medium cardboard About 0.13 mm) and Mondi (160 g / m ² , thickness about 0.19 mm) were used as cardboard.

  Table 2 shows the results of the fixing test, and the evaluation marks “x”, “Δ”, and “◯” in the table indicate that the toner image after the fixing process has a large peeling. “X” is indicated as an evaluation result, “Δ” is indicated when there is a minute peeling, and “◯” is indicated when there is no peeling.

  As apparent from the table, in Test 1 in which the fixing device is set to the thin paper mode using the above thin paper at the paper passing speed Vp1 = 70 mm / s, the load on one side is low load F1 = 10 kgf, and the nip width N1 = 4 mm. The compression ratio of the elastic layer was 5.0%, and good fixability could be obtained in the fixing temperature range of 140 to 180 ° C. Further, in Test 2 in which the above-described medium thick paper is used and the fixing device is set to the medium thick paper mode, the load on one side is medium load F2 = 12 kgf, the nip width N2 = 5 mm, the elastic layer compressibility = 10.0%, and the fixing temperature 160 Good fixability could be obtained in the range of ˜180 ° C. Further, in Test 3 in which the fixing device is set to the thick paper mode using the above-described thick paper, the one-side load is high load F3 = 16 kgf, the nip width N3 = 6 mm, the elastic layer compressibility = 14.6%, and the fixing temperature is 170˜ Good fixability could be obtained in the range of 180 ° C.

  Next, in Test 4 in which the fixing device is set to the medium-thick paper mode using the above-described thick paper at a paper passing speed Vp1 = 70 mm / s, the one-side load is low load F2 = 12 kgf, the nip width N2 = 5 mm, and the elastic layer compression The ratio was 10.0%, and good fixability could be obtained only at a fixing temperature of 180 ° C. Furthermore, in Test 5 in which only the sheet passing speed was Vp2 = 59 mm / s under the conditions of Test 4, good fixability could be obtained in the fixing temperature range of 170 to 180 ° C.

  As is clear from the comparison between the test 4 and the test 5, it is understood that the fixing property is improved by reducing the sheet passing speed even when the one side load is the same medium load F2 = 12 kgf.

  Here, the relationship between the compression rate of the heat-resistant elastic layer 302 of the fixing roller 30 of the fixing device 3, the nip width, and the reference sheet passing speed will be described. FIG. 8 is a graph showing the relationship between the compression rate (%) of the heat-resistant elastic layer 302 of the fixing roller 30 of the fixing device 3, the nip width (mm), and the sheet passing speed (PPM). The reference sheet passing speed here is an upper limit sheet passing speed at which good fixability can be obtained in a predetermined fixing temperature range (170 to 180 ° C. here). Here, thick paper is used. And tested.

As is apparent from the figure, the nip width and the elastic compressibility are substantially directly proportional, and the nip width and the reference sheet passing speed are also substantially directly proportional. In the graph of FIG. 8, the scale of the reference sheet feeding speed is adjusted and described so that the proportional lines of the two coincide. From this graph, for example, in the case of thick paper, when the elastic compressibility is 10%, the nip width is 5 mm, and when this nip width is 5 mm, the reference paper passing speed is about 10 PPM. It can be seen that by reducing the speed, the elastic compressibility can be lowered while maintaining a good fixing state.
Here, the sheet passing speed unit PPM represents the number of recording sheets to be passed in one minute. In the image forming apparatus 1 using the A4 recording sheet, 10 PPM is the sheet passing speed Vp2 = 59 mm / s. And 12 PPM corresponds to the sheet passing speed Vp1 = 70 mm / s.

  FIG. 9 is based on the test results described above. When the thick paper is used without setting the thick paper mode in which the elastic layer compression ratio = 14.6% and exceeds 14%, the medium thick paper mode is used. 6 is a flowchart illustrating a print processing method according to the present embodiment, in which a favorable fixing state is maintained by switching the sheet passing speed as it is. Based on this flowchart, the printing operation in the present embodiment by the image forming apparatus 1 will be described below with reference to FIGS.

  First, in order to initialize the load F to the pressure roller 32 prior to the printing operation performed by receiving the print data from the external device received by the print data receiving unit 43 (FIG. 5), the low load F1 (for thin paper) ), The eccentric cam 36 is rotated by the motor 27, the eccentric cam 36 is set to the thin paper mode shown in FIG. 4A (step S201), and the sheet passing speed is set to the normal speed, here, as described above. The first sheet passing speed Vp1 is set to 70 mm / s (step S202).

  When the image forming operation is started, the recording paper 50 accommodated in the paper feeding cassette 18 is separated and fed out one by one by the paper feeding rollers 19a and 19b and the separating piece 20, and is conveyed to the registration roller 22 by the conveying roller 21. (Step S203). Here, the paper thickness reading sensor 25 detects a change in roller position when the recording paper 50 passes through the registration roller 22 to detect the paper thickness, and transmits the detected paper thickness information to the control unit 26. The thickness information is captured by the control unit 26 (step S204). In this state, the conveyance of the recording paper 50 is temporarily stopped. During this conveyance pause period, the processing from step S205 to step S211 described below is executed.

  That is, first, it is determined whether or not the recording paper 50 detected here is a thin paper (step S205). If it is determined that the recording paper 50 is thin (the paper thickness is 0.07 mm or more and less than 0.1 mm) (Yes in step S205), the output of the cam position sensor 28 is taken in, and the eccentric cam 36 is shown in FIG. It is confirmed whether or not it is in the thin paper mode position shown in FIG. If the eccentric cam 36 is in the thin paper mode position (step S206, Yes), the process proceeds to step S212 as it is. If the eccentric cam 36 is not in the thin paper mode position (step S206, No), processing for changing to the thin paper mode is performed. (Step S207), and then the process proceeds to Step S212.

  On the other hand, if it is determined in step S205 that the recording paper 50 is not a thin paper (No in step S205), it is further determined whether or not the recording paper 50 detected here is a medium thick paper (step S208). If it is determined that the recording paper 50 is medium-thick paper (paper thickness is 0.1 mm or more and less than 0.16 mm) (step S208, Yes), the process proceeds to step S210, and if it is determined that the recording paper 50 is not medium-thick paper (step S208). No), it is determined that the recording paper 50 detected here is thick paper (paper thickness is 0.16 mm to 0.25 mm), and the paper feeding speed is low, here the second paper feeding speed Vp2 described above. = 59 mm / s (step S209), and then the process proceeds to step S210.

  In step S210, the output of the cam position sensor 28 is taken in, and it is confirmed whether or not the eccentric cam 36 is in the middle thick paper mode position shown in FIG. 4B, and if it is in the middle thick paper mode position (step S210). Yes), the process proceeds to step S212 as it is, and if it is not the position of the medium cardboard mode (No in step S210), the process for changing to the medium cardboard mode is performed (step S211), and then the process proceeds to step S212.

  After the setting of the load F of the pressure roller 32 and the setting of the sheet passing speed Vp by the speed control unit 41 (FIG. 5) in the processing of the above steps S205 to S211, the printing paper 50 by the registration roller 22 is set. The conveyance is resumed, and an image forming operation based on the electrophotographic process (charging, exposure, development, transfer, fixing) is performed (step S212).

  Thereafter, it is confirmed whether or not there is a page to be imaged next (step S213). If there is an unprocessed page (step S213, Yes), the process returns to step S202 and the processes of steps S202 to S212 are performed. If no unprocessed pages remain (step S213, No), the output of the cam position sensor 28 is taken in order to reinitialize the load F to the pressure roller 32, and the eccentric cam 36 is shown in FIG. ) To determine whether it is in the thin paper mode position (step S214). If the eccentric cam 36 is in the thin paper mode position (step S214, Yes), the image forming process is terminated, and if it is not in the thin paper mode position (step S214, No), the process for changing to the thin paper mode is performed. (Step S215), and then the image forming process is terminated. Therefore, the setting operation of the load F of the pressure roller 32, the sheet passing speed setting operation, and the image forming operation are executed for each recording sheet until there is no print data.

  Therefore, according to this flow, when the paper thickness of the recording paper to be used is thin paper or medium thick paper with the fixing temperature set to a predetermined value in a predetermined temperature range (170 to 180 ° C. in this case), The load F applied to the pressure roller 32 is appropriately within a predetermined range according to the paper thickness at a normal paper feeding speed (here, the range in which the compression rate of the heat resistant elastic layer 302 of the fixing roller 30 is 14% or less). When the necessary nip width N is set and the recording paper to be used is thick, the sheet F is passed with the load F kept at a medium load F2 = 12 kgf (corresponding to the compression ratio of 10%). A good fixing state is maintained by reducing the speed. Therefore, a good fixing state can be maintained regardless of the paper thickness of the recording paper used without setting the compression rate of the heat-resistant elastic layer 302 to 14% or more.

  As described above, according to the image forming apparatus of the present embodiment, the compression rate of the heat-resistant elastic layer 302 of the fixing roller 30 is set within a predetermined range (here, 14% or less), and the fixing temperature setting is kept the same. A good fixing state can be maintained regardless of the thickness of the recording paper used. For this reason, a good fixing state can be maintained without reducing the durable number of printed sheets.

Embodiment 3 FIG.
FIG. 10 is a main part configuration diagram showing the main part configuration of the fixing device employed in the image forming apparatus of the third embodiment based on the present invention.

  The image forming apparatus employing the fixing device 503 is mainly different from the fixing device 3 of the first embodiment shown in FIG. 2 in that the fixing device 3 of the first embodiment is a heat roller system. The fixing device 503 of this embodiment is a fixing device using the fixing belt 504 (hereinafter referred to as a fixing belt system). Therefore, in the image forming apparatus employing the fixing device 503, the same reference numerals are given to the parts common to the image forming apparatus 1 (FIG. 1) of the first embodiment described above, or the description is omitted with the drawing omitted. And focus on the differences. The main part configuration of the image forming apparatus according to the present embodiment is the same as that of the main part of the image forming apparatus 1 according to the first embodiment shown in FIG. 1 except for the fixing device 503. Therefore, FIG. refer.

  As shown in FIG. 10, in the fixing device 503, a nip portion 60 for fixing the unfixed toner image 58 to the recording paper 50 is formed by pressing the fixing roller 530 and the pressure roller 532. . The pressure roller 532 receives a rotational force from a driving source (not shown) and rotates in a direction indicated by an arrow C at a predetermined speed, which will be described later. The bearings 34 and 34 are moved in the same manner as the pressure roller 32 in the first embodiment. The fixing roller 530 is pressed by the springs 35, 35 disposed therebetween, and the pressing force of the pressure roller 532 on the fixing roller 530 can be changed by the eccentric cams 36, 36. Since the configuration for driving the cam 36 is the same as that of the first embodiment, a detailed description thereof is omitted here.

  The fixing roller 530 is disposed inside the fixing belt 504 at a position facing the pressure roller 532, and forms a nip portion 60 having a nip width N via the fixing belt 504 by pressure contact with the pressure roller 532. ing. The fixing belt 504 is stretched between a fixing roller 530 and a belt support 505 provided with a sheet heating element 506. The sheet heating element 506 is disposed at a position where the surface thereof is in contact with the inner surface of the fixing belt 504 and applies heat to the sliding fixing belt 504 so that the temperature of the fixing belt 504 rises to a predetermined temperature. The temperature is controlled.

  When the pressure roller 532 receives a rotational force from a driving source (not shown) and rotates in the direction of arrow C, the frictional force between the pressure roller 532 and the fixing belt 504 and the frictional force between the fixing belt 504 and the fixing roller 530 cause The fixing belt 504 and the fixing roller 530 are driven to rotate in the directions of the arrows, respectively. The recording paper 50 onto which the toner image 58 has been transferred passes through the nip portion 60 together with a fixing belt 504 heated to a predetermined temperature, which will be described later, and unfixed toner is fixed to the recording paper 50 by pressure and heating. It has become.

  The fixing roller 530 has a configuration in which a foamed silicone rubber (sponge) layer 530b having a thickness of 7 mm is provided on a shaft core bar 530a made of iron and having an outer diameter of φ14 mm, and the outer diameter of the roller is φ28 mm. The pressure roller 532 is provided with a foamed silicone rubber (sponge) layer 532b having a layer thickness of 2 mm on a hollow metal core (core metal thickness 1 mm) 532a made of iron and having an outer diameter of φ24 mm, and a layer thickness as a toner release layer 532c on the surface layer. A three-layer structure is provided with a 0.03 mm fluororesin (PFA) tube layer, and the outer diameter of the roller is φ28 mm. As described above, the hollow metal core 532a is rotatably held by the rotating shaft 34 and is configured to receive a rotational force from a driving source (not shown).

  The fixing belt 504 is a thin seamless belt including a heat resistant resin layer, an elastic layer, and a surface layer (not shown). The heat-resistant resin layer is made of polyimide resin and has a thickness of 0.08 mm and an inner diameter of φ36 mm. The upper (outer) elastic layer is made of a silicone rubber layer having a layer thickness of 0.3 mm. The surface layer serving as the toner release layer is composed of a fluororesin (PFA) tube layer having a layer thickness of 0.03 mm.

  The belt support 505 is composed of a resin having high heat resistance such as PPS (polyphenylene sulfide), PEEK (polyether ether ketone), LCP (liquid crystal polymer), and glass fiber, What strengthened by adding glass beads etc. may be used. Further, a lubricant such as fluorine grease may be used between the fixing belt 504 and the belt support 505 to reduce friction.

FIG. 11 is an exploded perspective view illustrating a configuration example of the planar heating element 506.
As shown in the figure, the planar heating element 506 is provided with an electric insulating layer 506b such as glass on a substrate 506a such as stainless steel or ceramic, and a resistor made of nickel-chromium alloy or silver-palladium alloy powder on the insulating layer 506b. A material that is coated with the heating element 506c and further protected with a protective layer 506d made of glass, fluorine resin (PFA, PTFE, FEP) or the like is used. Further, the sheet heating element 506 may have a curvature similar to the curvature of the outer surface in contact with the fixing belt 504 of the belt support 505 over which the fixing belt 504 is stretched.

  The fixing belt system configured as described above is useful for increasing the printing speed and shortening the rise time. In the present embodiment, similarly to the second embodiment, the load F for pressing the pressure roller 532 or the sheet passing speed Vp of the recording paper is appropriately changed.

  Here, the relationship between the compression rate of the foamed silicone rubber (elastic) layer 530b of the fixing roller 530 of the fixing device 503 and the durable sheet passing number will be described. FIG. 12 is a graph showing the relationship between the compression rate of the foamed silicone rubber (elastic) layer 530b of the fixing roller 530 of the fixing device 503 and the durable sheet passing number.

  In the graph of the figure, the compression rate of the foamed silicone rubber (elastic) layer 530b of the fixing roller 530 of the fixing device 503 is set to various values (10, 13, 14, 15, 16, 18, 19, 20 (%)). A recording sheet in which a fixing durability test is performed using a fixing device, and a visible printing defect occurs in the fixed toner image due to deterioration of the foamed silicone rubber (elastic) layer 530b, that is, rubber deterioration (softening, curing, etc.) Are plotted as the number of durable sheets. In this example, a medium-thick recording paper is used and continuous paper feeding is performed at a 5% printing duty, the paper feeding speed is 28 PPM, and the fixing temperature is set in a range of 170 ° C. to 180 ° C. Here, the compression rate of the foamed silicone rubber (elastic) layer 530b is the ratio of the compression width of the maximum compression portion in the nip portion 60 (FIG. 2) to the layer thickness of the foamed silicone rubber (elastic) layer 530b.

  As shown in the graph of FIG. 12, when the printing speed is set to 28 PPM, when the vicinity of each plotted point is connected by a plurality of straight lines, the intersection of the straight lines with different inclinations, that is, the changing point is in the vicinity of a compression rate of 15%. It can be seen that when the compression ratio exceeds 15, the number of durable sheets is remarkably reduced. For this reason, it is understood that the durability of the fixing device can be improved by performing the fixing operation in a region where the compression rate is 15% or less.

  Next, a description will be given of printing tests and results obtained by variously setting the load F for pressing the pressure roller 532 or the sheet passing speed Vp of the recording sheet with respect to printing sheets having different sheet thicknesses.

The fixing test was performed under the following conditions.
(1) As a test device, a fixing device that can be set to a thin paper mode (low load F1 = 16 kgf), a medium thick paper mode (medium load F2 = 18 kgf), and a thick paper mode (high load F3 = 22 kgf) is provided, and further, a paper passing speed is provided. Used is an image forming apparatus capable of setting Vp1 = 167 mm / s and Vp2 = 143 mm / s.
(2) The toner density (each color single color) of the end-fixed recording paper was set to 100% printing duty.
(3) The fixing temperature of the fixing device was set in five stages at intervals of 10 ° C. in the range of 140 to 180 ° C.
(4) Fuji Xerox Co., Ltd. P paper A4 (64 g / m ² , thickness of about 0.07 mm) as thin paper, Oki Data Co., Ltd. Excellent White A4 thick mouth (105 g / m ² , thickness) as medium cardboard About 0.13 mm) and Mondi (160 g / m ² , thickness about 0.19 mm) were used as cardboard.

  Table 3 shows the results of the fixing test, and the evaluation marks “x”, “Δ”, and “◯” in the table indicate that the toner image after the fixing process is largely peeled off. “X” is indicated as an evaluation result, “Δ” is indicated when there is a minute peeling, and “◯” is indicated when there is no peeling.

  As is apparent from the table, in Test 1 in which the fixing device is set to the thin paper mode using the thin paper at the paper passing speed Vp1 = 167 mm / s, the one-side load is low load F1 = 16 kgf, and the nip width N1 = 10 mm. The elastic layer compression rate was 10.7%, and good fixability could be obtained in the fixing temperature range of 140 to 180 ° C. In Test 2 in which the fixing device is set to the medium-thick paper mode using the above-mentioned medium-thick paper, the one-side load is medium load F2 = 18 kgf, the nip width N2 = 11 mm, the elastic layer compression rate = 13.0%, and the fixing temperature 160 Good fixability could be obtained in the range of ˜180 ° C. Further, in Test 3 in which the fixing device is set to the thick paper mode using the above thick paper, the one-side load is high load F3 = 22 kgf, the nip width N3 = 12 mm, the elastic layer compressibility = 15.6%, and the fixing temperature 170 to Good fixability could be obtained in the range of 180 ° C.

  Next, in Test 4 in which the fixing device is set to the medium-thick paper mode using the above-mentioned thick paper at a paper passing speed Vp1 = 167 mm / s, the one-side load is low load F2 = 18 kgf, the nip width N2 = 11 mm, and the elastic layer compression The rate was 13.0%, and good fixability could be obtained only at a fixing temperature of 180 ° C. Furthermore, in Test 5 in which only the sheet passing speed was Vp2 = 143 mm / s under the conditions of Test 4, good fixability could be obtained in the fixing temperature range of 170 to 180 ° C.

  As is clear from the comparison between Test 4 and Test 5, it can be seen that the fixability is improved by slowing the sheet passing speed even if the one-side load is the same medium load F2 = 18 kgf. Here, the sheet passing speed unit PPM represents the number of recording sheets to be passed in one minute. In the image forming apparatus 1 using the A4 recording sheet, 28 PPM corresponds to the sheet passing speed Vp1 = 167 mm / s. To do.

  Based on the above test results, the elastic layer compression rate = 15.6%, and without using the cardboard mode exceeding 15%, when using cardboard, it is good by switching the speed. A print processing method according to the present embodiment for maintaining the fixed state will be described.

Here, printing is executed according to the same flow as the printing processing method shown in FIG. 9 performed in the second embodiment. However, here
Low load F1 = 16 kgf (thin paper mode),
Medium load F2 = 18 kgf (medium cardboard mode),
High load F3 = 22 kgf (cardboard mode)
Paper passing speed Vp1 = 167 mm / s
The sheet passing speed Vp2 = 143 mm / s.

  Therefore, according to this flow, when the paper thickness of the recording paper to be used is thin paper or medium thick paper with the fixing temperature set to a predetermined value in a predetermined temperature range (170 to 180 ° C. in this case), At a normal paper feeding speed (Vp1 = 167 mm / s), the load F to the pressure roller 532 is appropriately within a predetermined range according to the paper thickness (here, the foamed silicone rubber (elastic) layer 530b of the fixing roller 530). When the required nip width N is formed by setting the compression ratio to be 15% or less, and the recording paper used is thick, the load F is medium load F2 = 18 kgf (the above compression ratio) In this case, the fixing state is maintained by lowering the sheet passing speed (Vp2 = 143 mm / s). Therefore, a good fixing state can be maintained regardless of the thickness of the recording paper used without setting the compression rate of the foamed silicone rubber (elastic) layer 530b to be greater than 15%.

  As described above, according to the image forming apparatus of the present embodiment, the compression rate of the foamed silicone rubber (elastic) layer 530b of the fixing roller 530 is set within a predetermined range (here, 15% or less), and the fixing temperature setting is the same. As a result, a good fixing state can be maintained regardless of the thickness of the recording paper used. For this reason, a good fixing state can be maintained without reducing the durable number of printed sheets.

In each of the embodiments described above, special paper such as OHP sheets, cards, postcards, thick paper with a weight equivalent to 200 g / m ² or more, envelopes, coated paper with a large heat capacity, etc. is used as a recording medium in addition to plain paper. be able to.
In each of the above-described embodiments, the thickness is automatically detected by the paper thickness reading sensor, and the cam motor control is performed based on the detection result. However, the present invention is not limited to this. The cam motor may be controlled according to the thickness setting by the input to the control unit 26 from the unit.
In each of the embodiments described above, in the flowchart showing the flow of the printing process, the cam position is initialized to F1 (thin paper) first (step S101), and then the judgment is made in the order of thin paper, medium thick paper, and thick paper. Although the cam position (F1, F2, F3) was controlled, the present invention is not limited to this. The cam position is first initialized to F3 (thick paper), and then the thick paper, medium thick paper, and thin paper are processed in this order. Thus, the cam positions (F1, F2, F3) may be controlled.
Further, the fixing device may take various forms such as being integrally attached to the main body of the image forming apparatus or being detachable from the main body of the image forming apparatus.

  In each embodiment, a color electrophotographic printer is described as an example. However, the present invention can be applied to a facsimile machine, a copying machine, a multifunction machine, and the like.

  DESCRIPTION OF SYMBOLS 1 Image forming apparatus, 3 Fixing apparatus, 11 Image forming unit, 12 Photosensitive drum, 13 Transfer roller, 14 Conveyor belt, 16 Exposure apparatus, 17 Upper cover, 18 Paper feed cassette, 19 Paper feed roller, 20 Separation side, 21 Transport roller pair, 22 Registration roller pair, 23 Discharge roller pair, 24 Discharge transport roller pair, 25 Paper thickness reading sensor, 26 Control unit, 27 Cam motor, 28 Pressure cam position sensor, 30 Fixing roller, 31 Drive gear, 32 Addition Pressure roller, 33 Halogen heater, 34 Bearing, 35 Spring, 36 Eccentric cam, 37 Spring receiving member, 37a Rotating shaft, 38 Drive shaft, 39 Bearing, 41 Medium transport motor, 42 Fixing controller, 42a Temperature controller 42b Pressurization amount control unit 50 recording paper, 51 paper sensor, 52 paper sensor, 53 writing sensor, 54 paper sensor, 55 drive roller, 56 idle roller, 58 toner image, 60 nip portion, 101 charging roller, 102 developing roller, 103 toner supply portion, 104 Cleaning blade, 301 core metal outer peripheral surface, 302 heat resistant elastic layer, 303 fluorine resin layer, 321 core metal outer peripheral surface, 322 heat resistant elastic layer, 323 fluoro resin layer, 350 thermistor, 503 fixing device, 504 fixing belt, 505 belt support 506, sheet heating element, 506a substrate, 506b electric insulation layer, 506c resistance heating element, 506d protective layer, 530 fixing roller, 530a shaft core, 530b foamed silicone rubber (sponge) , 532 pressure roller, 532a hollow core metal, 532b fire silicone rubber (sponge) layer, 532c toner release layer.

Claims (12)

In an image forming apparatus including a fixing device that fixes a developer attached to a print medium by applying heat and pressure,
A heating unit for heating the print medium;
Pressurizing the heating unit to form a predetermined nip with the heating unit; and
A transport driving means for driving at least one of the heating unit and the pressure unit to transport the print medium in a predetermined direction through the nip portion at a predetermined transport speed;
Pressurizing amount control means for controlling the pressurizing amount by the pressurizing unit
The image forming apparatus, wherein the pressurizing amount control unit controls the pressurizing amount by the pressurizing unit in accordance with the type of the printing medium.   The image forming apparatus according to claim 1, wherein the pressurizing amount control unit gradually increases the pressurizing amount by the pressurizing unit as the thickness of the printing medium increases.   3. The image forming apparatus according to claim 2, further comprising a conveyance speed setting unit capable of switching the conveyance speed between a first conveyance speed and a second conveyance speed that is slower than the first conveyance speed. Image forming apparatus.   The heating unit includes a fixing roller having a silicone rubber layer and a heating element provided inside the fixing roller, and the nip portion is formed on an outer peripheral surface of the fixing roller. The image forming apparatus according to 1 or 2.   The heating unit includes a fixing roller having a silicone rubber layer and a heating element provided in the fixing roller. The nip portion is formed on the outer peripheral surface of the fixing roller, and the compression rate of the fixing roller is When the maximum value that does not exceed the upper limit is set, the transport speed is increased from the first transport speed to the first transport speed without increasing the pressurization amount with respect to the further increase in the thickness of the print medium. The image forming apparatus according to claim 3, wherein the image forming apparatus is switched to a conveyance speed of 2.   The heating unit includes a fixing roller having a foamed silicone rubber layer, a belt support provided with a heat generating unit, and a belt body stretched between the fixing roller and the belt support. The image forming apparatus according to claim 1, wherein the nip portion is formed on an outer peripheral surface of the image forming apparatus.   The heating unit includes a fixing roller having a foamed silicone rubber layer, a belt support provided with a heat generating unit, and a belt body stretched between the fixing roller and the belt support. In the case where the nip portion is formed on the outer peripheral surface and the compression rate of the fixing roller is set to a maximum value that does not exceed the upper limit value, the pressurization amount with respect to a further increase in the thickness of the print medium The image forming apparatus according to claim 3, wherein the transport speed is switched from the first transport speed to the second transport speed without increasing the speed.   6. The image forming apparatus according to claim 5, wherein the upper limit value of the compression rate is 14%.   The image forming apparatus according to claim 7, wherein the upper limit value of the compression rate is 15%.   9. The image forming apparatus according to claim 8, wherein the first conveyance speed is 12 PPM and the second conveyance speed is 10 PPM.   The image forming apparatus according to claim 9, wherein the first transport speed is 28 PPM and the second transport speed is 24 PPM.   The printing medium thickness detector is provided, and the pressurization amount control means recognizes the thickness of the printing medium based on information from the printing medium thickness detector. 2. The image forming apparatus according to item 1.

Images