The present disclosure relates to image forming apparatuses including a heating apparatus.
Electrophotographic image forming apparatuses generally include a heating apparatus that heats toner transferred to sheets in order to fix the toner to the sheets. U.S. Patent Application Publication No. 2021/0072681 discloses a heating apparatus including a plurality of heating elements of different lengths in a longitudinal direction perpendicular to a sheet conveying direction. This heating apparatus adjusts the ratio of power to be supplied to the individual heating elements.
However, for example, depending on the longitudinal length of the sheets, adjusting the power ratio to a power ratio different from a predetermined power ratio is also required.
The present disclosure provides a unit configured to control the power ratio in accordance with the situation.
A heating apparatus according to an aspect of the present disclosure includes a first rotatable member, a heater disposed in an inner space of the first rotatable member, first and second temperature detection units configured to detect a temperature of the heater, and a control unit configured to control power to be supplied to the heater. The heater includes a long narrow substrate, a first heating element, and a second heating element, the first and second heating elements being disposed on the substrate. A direction of a long side of a surface of the substrate on which the heating element is disposed is a longitudinal direction, a direction perpendicular the longitudinal direction of the surface is a crosswise direction, and a direction perpendicular to the longitudinal direction and the crosswise direction is a thickness direction, a length of the first heating element in the longitudinal direction is longer than a length of the second heating element in the longitudinal direction, the second temperature detection unit is disposed closer to an end of the heater in the longitudinal direction than the first temperature detection unit. In response to the second temperature detection unit detecting a first temperature, the control unit sets a power ratio between the first heating element and the second heating element to a first value, and in response to the second temperature detection unit detecting a second temperature higher than the first temperature, the control unit sets the power ratio to a second value greater than the first value.
According to an aspect of the present disclosure, the power ratio can be controlled according to the situation.
Further features of the present disclosure will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Embodiments of the present disclosure will be described hereinbelow with reference to the drawings. In these embodiments, conveying a sheet to a fixing nip portion is also referred to as “passing a sheet”. Of the region in which heating elements generate heat, an area corresponding to a region through which the sheet is not passing is also referred to as “non-sheet passing region (or non-sheet passing portion). A region through which the sheet is passing is also referred to as “sheet passing region (sheet passing portion).
A phenomenon in which the temperature of the non-sheet passing region is higher than that of the sheet passing region is also referred to as “an increase in non-sheet passing portion temperature”. In contrast, a phenomenon in which the temperature of the non-sheet passing region is lower than that of the sheet passing region is also referred to as “a decrease in end temperature”.
A photosensitive drum 1a, which is an image bearing member, in the first station is an organic photoconductor (OPC) drum. The photosensitive drum 1a is a laminate of a plurality of functional organic materials, on a metallic cylinder, including a carrier forming layer that is exposed to light to generate an electric charge and a charge transport layer that transports the generated electric charge, of which the outermost layer has low electrical conductivity and is nearly insulating. A charging roller 2a, which is a charging unit, is in contact with the photosensitive drum 1a and uniformly charges the surface of the photosensitive drum 1a while being rotated with the rotation of the photosensitive drum 1a. The charging roller 2a receives a superimposed direct-current voltage or alternating-current voltage to cause electric discharge in minute air gaps upstream and downstream in the rotating direction from a nip portion between the charging roller 2a and the surface of the photosensitive drum 1a, thereby charging the photosensitive drum 1a. A cleaning unit 3a is a unit for cleaning toner remaining on the photosensitive drum 1a after the transfer, described later. A developing unit 8a for development includes a developing roller 4a, a non-magnetic monocomponent toner 5a, and a developer application blade 7. The photosensitive drum 1a, the charging roller 2a, the cleaning unit 3a, and the developing unit 8a constitute an integrated process cartridge 9a that is detachably mounted to the image forming apparatus.
An exposing unit 11a for exposure is constituted by a scanner unit that scans laser light using a polygonal mirror or a light-emitting diode (LED) array and emits a scanning beam 12a modulated in response to an image signal onto the photosensitive drum 1a. The charging roller 2a is connected to a charging high-voltage power source 20a for supplying a voltage to the charging roller 2a. The developing roller 4a is connected to a developing high-voltage power source 21a for supplying a voltage to the developing roller 4a. A primary transfer roller 10a is connected to a primary transfer high-voltage power source 22a for supplying a voltage to the primary transfer roller 10a.
This is the configuration of the first station. Second, third, and fourth stations have the same configuration. For the other stations, components having the same function as in the first station are given the same reference signs, and suffixes b, c, and d are added to the signs of the individual stations. In the following description, the suffixes a, b, c, and d may be omitted except when a specific station is described.
An intermediate transfer belt 13 is supported by three rollers: a secondary transfer facing roller 15, a tension roller 14, and an auxiliary roller 19 serving as stretching members. Only the tension roller 14 is given a force in the direction of stretching the intermediate transfer belt 13 by a spring to keep appropriate tension to the intermediate transfer belt 13.
The secondary transfer facing roller 15 is rotated by the rotary drive from a main motor (not shown) to rotate the intermediate transfer belt 13 wound therearound. The intermediate transfer belt 13 moves forward (for example, clockwise in
Next, the image forming operation of the image forming apparatus of the first embodiment will be described. Upon receiving a print instruction during standby, the image forming apparatus starts the image forming operation. The photosensitive drum 1 and the intermediate transfer belt 13 start to be rotated in the direction of arrow so as to reach a predetermined process speed by the driving force from a main motor (not shown). The photosensitive drum 1a is uniformly charged by the charging roller 2a subjected to a voltage by the charging high-voltage power source 20a, and then an electrostatic latent image according to image information is formed by a scanning beam 12a emitted from the exposing unit 11a.
Toner 5a in the developing unit 8a is charged to negative polarity by the developer application blade 7a and is applied to the developing roller 4a. The developing roller 4a is supplied with a predetermined developing voltage by the developing high-voltage power source 21a. When the photosensitive drum 1a rotates, so that the electrostatic latent image formed on the photosensitive drum 1a reaches the developing roller 4a, the negative-polarity toner adheres to the electrostatic latent image to visualize it, so that a first color (for example, yellow (Y)) toner image is formed on the photosensitive drum 1a. The stations (process cartridges 9b to 9d) of the other colors: magenta (M), cyan (C), and black (K) also operate in the same way.
Electrostatic latent images due to exposure are formed on the photosensitive drums 1a to 1d in response to delayed write signals from a controller (not shown) at a constant timing in accordance with the distance between the primary transfer positions of the individual colors. The primary transfer rollers 10a to 10d receive direct-current high voltages of a polarity opposite to the toner. With the above processes, the toner images are transferred to the intermediate transfer belt 13 in sequence (hereinafter also referred to as primary transfer) to form a multiple toner image on the intermediate transfer belt 13.
Thereafter, sheets P, for example, paper, placed in a paper cassette 16 are conveyed along the conveying path in accordance with the formation of the toner image. Specifically, each sheet P is fed (picked up) by a sheet feeding roller 17, which is rotationally driven by a sheet feeding solenoid (not shown). The fed sheet P is conveyed to registration rollers 18 by a conveying roller. The sheet P is conveyed to a transfer nip portion, which is a contact portion between the intermediate transfer belt 13 and the secondary transfer roller 25, by the registration rollers 18 in synchronization with the toner image on the intermediate transfer belt 13. The secondary transfer roller 25 receives a voltage of a polarity opposite to the polarity of the toner from a secondary transfer high-voltage power source 26, so that the four-color multiple toner image carried on the intermediate transfer belt 13 is transferred onto the sheet P in a single step (hereinafter also referred to as secondary transfer).
The members responsible for forming the unfixed toner image on the sheet P (for example, the photosensitive drum 1) function as an image forming unit. In contrast, the toner remaining on the intermediate transfer belt 13 after the completion of the secondary transfer is cleaned by a cleaning unit 27. The sheet P after the completion of the secondary transfer is conveyed to a fixing unit 50 for fixing. The toner image is heated and pressed by the fixing unit 50 and is discharged as image formed matter (a print or a copy) to a discharge tray 30. A film 51, a heater holder (a nip forming member) 52, a pressure roller 53, and a heater 54 of the fixing unit 50 will be described later.
The video controller 91 converts the image data from the PC 110 to exposure data and transfers the exposure data to an exposure control unit 93 in an engine controller 92. The exposure control unit 93 is controlled by a central processing unit (CPU) 94 and controls the on/off of the exposure data and the exposing unit 11. The size of the exposure data is determined by the size of the image size. Upon receiving the print instruction, the CPU 94 starts an image forming sequence.
The engine controller 92, serving as a control unit, includes the CPU 94 and a memory 95 and performs a programmed operation. A high-voltage power source 96 includes the charging high-voltage power source 20, the developing high-voltage power source 21, the primary transfer high-voltage power source 22, and the secondary transfer high-voltage power source 26 described above. A fixing-power control unit 97 includes a bidirectional thyristor (hereinafter also referred to as a triac) 56 and an electromagnetic relay 57 serving as a switch for exclusively selecting a heating element that supplies power. The fixing-power control unit 97 selects a heating element that generates heat in the fixing unit 50 to determine the amount of power to be supplied.
The drive unit 98 includes a main motor 99 and a fixing motor 100. A sensor 101 includes fixing temperature sensors 59, 60, and 61 for detecting the temperature of the fixing unit 50. The detection result of the sensor 101 is transmitted to the CPU 94. The CPU 94 obtains the detection result of the sensor 101 in the image forming apparatus and controls the exposing unit 11, the high-voltage power source 96, the fixing-power control unit 97, and the drive unit 98. Thus, the CPU 94 controls the image forming process of forming an electrostatic latent image, transferring the developed toner image, and fixing the toner image to the sheet P so that the exposure data is printed as a toner image on the sheet P. The image forming apparatus to which the present disclosure is applied is not limited to the image forming apparatus with the configuration illustrated in
Next, the configuration of the fixing unit 50 of the first embodiment will be described with reference to
The sheet P carrying an unfixed toner image Tn is heated and pressed at the fixing nip portion N while being conveyed from the left to right in
The film 51 is a fixing film serving as a heating rotatable member. In the first embodiment, its base layer contains, for example, polyimide. On the base layer, an elastic layer that contains silicone rubber and a releasing layer that contains perfluoroalkoxy alkane (PFA) are formed. The film 51 has grease on the inner surface to reduce the frictional force generated between the heater holder 52/the heater 54 and the film 51 due to the rotation of the film 51.
The heater holder 52 has the function of guiding the film 51 from the inside and forming the fixing nip portion N with the pressure roller 53, with the film 51 therebetween. The heater holder 52 is a rigid member with heat-resistant, heat-insulating properties and made of a liquid crystal polymer or the like. The film 51 is fitted on the heater holder 52. The pressure roller 53 serves as a pressurizing rotatable member. The pressure roller 53 includes a core metal 53a, an elastic layer 53b, and a releasing layer 53c. The pressure roller 53 is rotatably held at the opposite ends and is rotationally driven by the fixing motor 100 (see
The heater 54, serving as a heating member, is held by the heater holder 52 and is in contact with the inner surface of the film 51. The heater 54 is in contact with the film 51 as an example, but this is illustrative only. For example, a sliding plate may be provided between the heater 54 and the film 51. A substrate 54a, the heating elements 54b1a, 54b1b, 54b2, and 54b3, a protective glass layer 54e, and the fixing temperature sensors 59, 60, and 61 will be described later.
The heater 54 will be described in detail with reference to
The substrate 54a of this embodiment contains alumina (Al2O3), or ceramic. Well-known examples of the ceramic substrate include alumina (Al2O3), aluminum nitride (AlN), zirconia (ZrO2), and silicon carbide (SiC), among of which alumina (Al2O3) is inexpensive and easily available. The substrate 54a may also be composed of high-strength metal. A desirable example of the metal substrate is stainless steel (SUS), which excels in cost and strength. Both of the ceramic substrate and the metallic substrate, if having electrical conductivity, need only be provided with an insulating layer. The substrate 54a has thereon the heating elements 54b1a, 54b1b, 54b2, and 54b3, the conductor 54c, and the contact points 54d1 to 54d4, on which the protective glass layer 54e is formed to ensure insulation between the heating elements 54b1a, 54b1b, 54b2, and 54b3 and the film 51.
The heating elements 54b1a, 54b1b, 54b2, and 54b3 differ in the longitudinal length (the lateral length in
As shown in
As shown in
The resistance value of the heating element 54b1 is a combined resistance value of the resistance of the two heating elements 54b1a and 54b1b. The maximum power for each heating element per unit length is expressed as Eq. (1).
(power)/(length of heating element)=((input voltage)2/(resistance value))/(length of heating element) (1)
For example, in this embodiment, if the input voltage is 110 V, the maximum power per unit length (1 m) for the heating element 54b1 is 5,450 W/m; 2,145 W/m for the heating element 54b2; and 2,619 W/m for the heating element 54b3 from Eq. (1). Thus, the maximum power per unit length differs among the heating elements 54b1, 54b2 and 54b3.
The fixing temperature sensors 59, 60, and 61 shown in
The thermistor 59 includes a thermistor element 59a, a holder 59b, ceramic paper 59c, and an insulating resin sheet 59d. The ceramic paper 59c has the function of blocking the thermal conduction between the holder 59b and the thermistor element 59a. The insulating resin sheet 59d has the function of protecting the thermistor element 59a physically and electrically. The thermistor element 59a changes in output value according to the temperature of the heater 54. The thermistor element 59a is connected to the CPU 94 via a Dumet wire (not shown) and a wiring line. The thermistor element 59a detects the temperature of the heater 54 and outputs the detection result to the CPU 94.
The thermistor 59 is located, on an opposite surface of the substrate 54a from the protective glass layer 54e, at the position of the reference line a in the longitudinal direction of the heating element 54b (a position corresponding to the longitudinal center) and is in contact with the substrate 54a. The thermistors 60 and 61 also have the same cross-sectional configuration.
Thermistor 59 is also referred to as a main thermistor 59. The CPU 94 controls the power to be supplied to the heater 54 based on the detection result of the main thermistor 59. The thermistors 60 and 61 are also referred to as sub-thermistors. Sub-thermistor elements 60a and 61a are disposed bilaterally symmetrically in the longitudinal direction with respect to the reference line a. The sub-thermistor elements 60a and 61a are arranged at the positions corresponding to the opposite ends of the heating element 54b3. The distance S3 between the sub-thermistor element 60a and the sub-thermistor element 61a is expressed as S3=142 mm and L3>S3. The sub-thermistors 60 and 61 are arranged at the opposite ends of the shortest heating element 54b3 to monitor an increase in the non-sheet passing portion temperature when a sheet narrower than 142 mm (for example, a sheet of A6 size (105 mm in width)) is passed.
All of the main thermistor 59 and the sub-thermistors 60 and 61 are arranged inside the width L3=154 mm of the shortest heating element 54b3. This is for the purpose of safely addressing a rare failure. For example, even if one of the thermistors 59, 60, and 61 breaks down and one of the heating elements 54b1, 54b2, and 54b3 receives an excessive voltage, the excessively high temperature can be detected by the other thermistors not broken, and the fixing unit 50 can be safely stopped. For this reason, the three thermistors 59, 60, and 61 are disposed inside in the width of the shortest heating element 54b3. In other words, the sub-thermistors 60 and 61 are disposed closer to the longitudinal ends than the main thermistor 59.
For example, when power is to be supplied from the alternating-current power source 55 to the heating element 54b1, the triac 56a is turned on to connect the alternating-current power source 55 and the contact point 54d4 of the heater 54, and the triac 56b is turned off. Thus, the heating elements 54b1 (54b1a and 54b1b) are connected to the alternating-current power source 55 via the contact points 54d2 and 54d4 of the heater 54.
When power is to be supplied from the alternating-current power source 55 to the heating element 54b2, the triac 56b is turned on to connect the alternating-current power source 55 and the electromagnetic relay 57 so that the contact point 54d3 of the heater 54 is connected to the triac 56b, and the triac 56a is turned off. Thus, one end of the heating element 54b2 is connected to the alternating-current power source 55 via the contact point 54d3 of the heater 54, the electromagnetic relay 57, and the triac 56b, and the other end of the heating element 54b2 is connected to the alternating-current power source 55 via the contact point 54d2 of the heater 54.
When power is to be supplied from the alternating-current power source 55 to the heating element 54b3, the triac 56b is turned on so that the electromagnetic relay 57 connects the contact point 54d3 of the heater 54 to the alternating-current power source 55, and the triac 56a is turned off. Thus, one end of the heating element 54b3 is connected to the alternating-current power source 55 via the contact point 54d3 of the heater 54 and the electromagnetic relay 57, and the other end of the heating element 54b3 is connected to the alternating-current power source 55 via the contact point 54d1 of the heater 54 and the triac 56b. The CPU 94 calculates the amount of power required to make the temperature of the heater 54 reach a target temperature suitable for image formation on the sheet P on the basis of the temperature information on the heater 54 detected by the fixing temperature sensor 59. This embodiment uses proportional-integral (PI) control for controlling the temperature of the heater 54. However, the method of control is illustrative only.
To supply power at a power ratio for making the temperature of the heater 54 reach a target temperature, the CPU 94 controls the triacs 56a and 56b and the heating element electromagnetic relay 57 to allocate the time for supplying power to the heating elements 54b1, 54b2, and 54b3. The switching of power supply to the heating elements 54b1, 54b2, and 54b3 is performed every four periods of the frequency of the alternating-current power source 55.
Assume that one cycle of the power supply time is 10, the time ratio of power supply to the heating elements 54b 1a and 54b1b (hereinafter also referred to as a power ratio) is 2, and the time ratio of power supply (power ratio) to the heating element 54b2 is 8. In this case, the alternating-current power source 55 is connected to the heating element 54b1 to supply power for 8 periods (=4×2). Thereafter, heating elements to be supplied with power are switched, and the alternating-current power source 55 is connected to the heating element 54b2 to supply power for 32 periods (=4×8). The switching of power supply is repeated. In other words, the power supply path is switched again to the heating element 54b1 to supply power to the heating element 54b1. In this embodiment, the power supply time ratio (power ratio) can be switched from 10:0 to 0:10 in increments of 1.
This embodiment achieves the power ratio for making the temperature of the heater 54 reach a target temperature by allocating the time of power supply from the alternating-current power source 55. However, this is illustrative only. The amount of power supplied to the heating elements may be allocated to achieve a target ratio using one or a combination of time, a voltage, and an electric current. For example, a desired power ratio may be achieved by providing each heating element with a triac and switching ON/OFF of each triac using the CPU 94 to control the amount of an electric current to be supplied to each heating element. The resolution of the ratio is not limited to 10, described above, and the ratio may be set to any resolution.
Next, a count temperature prediction method for predicting the temperature of the heater 54 of the fixing unit 50 will be described. This embodiment uses a count value to predict the temperatures of the components (for example, the film 51, the pressure roller 53, and the heater holder 52) of the fixing unit 50. The count value is stored in the CPU 94 or the memory 95 and increases by +1 every time one sheet P is subjected to a fixing process. For this reason, the count value increases as the number of sheets P subjected to the fixing process increases.
In a standby state after completion of the fixing process, the components of the fixing unit 50 is naturally cooled to decrease in temperature. The count value is counted down with time. Specifically, the count value is subtracted using an arithmetic expression using the elapsed time as a parameter in accordance with the measured cooling characteristics of each of the components of the fixing unit 50. The method for predicting the temperatures of the components of the fixing unit 50 on the basis of the count value in this way is referred to as a count temperature prediction method.
For example, the interval from a count value of 0 to a first target count value is set to zone 1, and the interval from the first target count value to a second target count value is set to zone 2. The interval from the second target count value to a third target count value is set to zone 3, and the interval from the third target count value onward is set to zone 4. In each zone, the timing of switching the power supply to the heating element 54b1 is set. Examples of the number of zones set include, but are not limited to, 4, and any plurality of zones may be set.
In this embodiment, four zones are set in which the first target count value is set to 30, the second target count value is set to 100, and the third target count value is set to 200. For example, assume that printing on the sheets P is started from a cold state of the fixing unit 50 (in which the count is 0). On completion of printing on 30 sheets P, that is, on completion of a fixing process on 30 sheets P, the count value reaches the first target count value 30. For this reason, on completion of printing on 30 sheets P, zone 1 ends and shifts to zone 2 from printing on the 31th sheet P.
The amount of heat generation required for the heating elements 54b1, 54b2, and 54b3 to fix an unfixed toner image formed on the sheet P changes according to the amount of heat stored in the heater 54 of the fixing unit 50. If the heater 54 of the fixing unit 50 is cold, a large amount of heat is required correspondingly, but if the heater 54 of the fixing unit 50 is warmed such as after continuous printing, the amount of heat required is small correspondingly.
Table 1 shows power required for each zone, described above, per unit length of the heater 54. The left column in Table 1 shows zones (1 to 4), and the right column shows power required for each zone per unit length of the heater 54 (in W/m (meter)).
The required power shown in Table 1 was determined by evaluating the toner fixing performance on the sheet P while experimentally changing the power for each zone. The values of the required power shown in Table 1 are rounded off to the first place.
Relationship between Input Voltage of Alternating-Current Power Source and Power Ratio of Heating Elements
In this embodiment, the maximum heat generation amount of the heating element 54b1, which is longest in the longitudinal direction, is the largest, as described above. This allows, when the heater 54 of the fixing unit 50 is cold, the waiting time until the heater 54 reaches the target temperature to be shortest by supplying maximum power to the heating element 54b1.
With the heater 54 of the fixing unit 50 warmed, the phenomenon of an increase in the temperature or the non-sheet passing portion occurs in which the temperature of the heater 54 of the fixing unit 50 increases gradually at the longitudinal ends of the heating element 54b1 through which the sheets P do not pass (non-sheet passing region). For this reason, an increase in the temperature of the non-sheet passing portion is reduced by switching to the heating element 54b2 or the heating element 54b3 in accordance with the size of the sheets P used.
However, since the maximum power for the heating elements 54b2 and 54b3 is set small, as described above, the required power for each zone cannot be achieved with a single element. For this reason, this embodiment uses the heating element 54b1 supplementally to compensate for the shortage of the required power. The required power decreases as the heater 54 of the fixing unit 50 becomes warm. This allows the ratio of power supplied to the heating element 54b1 to be decreased. If the increase in the temperature of the non-sheet passing portion is large, the power ratio of the heating element 54b1 is decreased to reduce the increase in temperature. Since the power ratio of the heating element 54b2 or 54b3 that require lower power increases relatively, the heat generation amount of the heater 54 decreases, providing the advantageous effect of reducing an increase in the temperature of the non-sheet passing portion.
A specific example of power supply control for continuous printing on A5-size sheets P at an input voltage of 110 V will be described. The image forming apparatus of this embodiment is capable of printing on A5-size sheets P at a productivity of 30 sheets per minute. In printing on A5-size sheets P, the fixing unit 50 performs a fixing operation while exclusively switching between the heating elements 54b1 and 54b3. When the input voltage is 110 V, the maximum power for the heating element 54b1 is 5,450 W/m, and the maximum power for the heating element 54b3 is 2,619 W/m.
Table 2 below shows the required power (in W/m), the power ratio when one cycle of the power supply period is 10, and the maximum power of the sheet-passing region (in W/m) of each zone. The sheet-passing region maximum power for each zone can be obtained from Eq. (2).
sheet-passing region maximum power=(maximum power for heating element 54b1)×(power ratio of heating element 54b1)+(maximum power for heating element 54b3)×(power ratio of heating element 54b3) (2)
Table 2 shows that the power ratio of the heating elements 54b1 and 54b3 in zone 1 is 7:3. Therefore, the sheet-passing region maximum power=(5,450 W/m)×(7/10)+(2,619 W/m)×(3/10)=3,815+785.7=4,600.7≈4,600 (W/m) (the first place is rounded) can be obtained from Eq. (2).
Table 2 shows that the power ratio of the heating elements 54b1 and 54b3 in zone 2 is 5:5. Therefore, sheet-passing region maximum power=(5,450 W/m)×(5/10)+(2,619 W/m)×(5/10)=2,725+1,309.5=4,034.5 4,030 (W/m) (the first is rounded) can be obtained from Eq. (2).
Table 2 shows that the power ratio of the heating elements 54b1 and 54b3 in zone 3 is 3:7. Therefore, the sheet-passing region maximum power=(5,450 W/m)×(3/10)+(2,619 W/m)×(7/10)=1,635+1,833.3=3,468.3 3,470 (W/m) (the first place is rounded) can be obtained from Eq. (2).
Table 2 shows that the power ratio of the heating elements 54b1 and 54b3 in zone 4 is 2:8. Therefore, the sheet-passing region maximum power=(5,450 W/m)×(2/10)+(2,619 W/m)×(8/10)=1,090+2,095.2=3,185.2≈3,190 (W/m) (the first place is rounded) can be obtained from Eq. (2).
Table 2 shows the required power, the power ratio, and the maximum power of the sheet-passing region of each zone. In any of the zones, the relationship of required power<sheet-passing region maximum power holds.
Sub-Thermistor and Throughput Reduction
Next, throughput reduction control according to the results of the sub-thermistors 60 and 61 will be described. The throughput reduction refers to decreasing production efficiency, or the number of sheets printed per unit time, by increasing the conveyance interval between the sheets P. In other words, the conveyance interval is the interval between the preceding sheet P and the following sheet P.
The distance S3 shown in
For this reason, the conveyance interval between the sheets P is increased to prevent the increase in the temperature of the non-sheet passing portion in accordance with the detection results of the sub-thermistors 60 and 61. During the fixing on the sheets P with the fixing unit 50, the conveyance interval is adjusted in accordance with the highest temperature detected by the sub-thermistors 60 and 61. The highest temperature detected by the sub-thermistors 60 and 61 is updated every time printing is performed on the sheets P. Table 3 shows the relationship between the highest temperature detected by the sub-thermistors 60 and 61 and the conveyance interval between the sheets P. For example, if the detection result of the sub-thermistor is 243° C., the temperature corresponds to Lv3, and the conveyance interval between the sheets P is set to 400 mm. The conveyance interval between the sheets P is set in accordance with the timing for feeding the next sheet P.
To illustrate the challenges in this embodiment, printing is performed under the conditions shown in Table 4. Table 4 shows conditions in printing three types of sheets P with different widths. Challenges when image formation is performed under these conditions will be described.
The zone in Table 4 indicates the degree of warming of the fixing unit 50 before printing. Zone 1 indicates that the fixing unit 50 is sufficiently cooled. In this state, continuous printing on 30 sheets P is performed. Table 2 shows that the power ratio is 7:3 under any conditions. The power supply is controlled so that the main thermistor 59 reads 210° C. Printing is started at an initial conveyance interval between the sheets P of 50 mm.
The thin solid line indicates condition A, the dashed-dotted line indicates condition B, and the thick solid line indicates condition C. Since the outputs of the sub-thermistors 60 and 61 were substantially the same,
Under condition A, the detection result of the sub-thermistor 60 fell below 230° C. even when image formation was performed on 30 sheets P, and the conveyance interval between the sheets P was not changed from 50 mm.
Under condition B, when image formation was performed on the fifth sheet P, the detection result of the sub-thermistor 60 exceeded 230° C. Table 3 shows that this is in the state of Lv2, in which the conveyance interval from the sixth sheet P increased from 50 mm to 200 mm. Thus, an increase in the conveyance interval suppressed an increase in the temperature of the non-sheet passing portion, resulting in a decrease in the temperature detected by the sub-thermistor 60.
Under condition C, when image formation was performed on the second sheet P, the detection result of the sub-thermistor 60 exceeded 240° C. Table 3 shows that this is in the state of Lv3, in which the conveyance interval from the third sheet P increased from 50 mm to 400 mm. Thus, like condition B, an increase in the conveyance interval suppressed an increase in the temperature of the non-sheet passing portion, resulting in a decrease in the temperature detected by the sub-thermistor 60.
The thin solid line corresponds to condition A, the dashed line corresponds to condition B, and the thick solid line corresponds to condition C.
This shows that the temperature in the longitudinal center was higher in order of conditions C, B, and A. This is because the increase in the conveyance interval between the sheets P decreased the frequency of the passage of the sheet P through the fixing unit, thereby reducing the amount of heat removed from the fixing unit 50. The fixing film can accumulate energy (heat) in the interval in which the sheets P are not passing through the fixing unit. In other words, an increase in the conveyance interval increases the temperature of the fixing film in the sheet passing region (longitudinal center).
The graph shows that the temperatures at the longitudinal ends are lower in order of condition C, B, and A. While the sheets P are passing through the fixing unit, the heat is removed by the sheets P, which makes the amount of energy (power) used per unit time larger than that in the interval through which the sheets P are not passing. An increase in the conveyance interval increases a period during which the sheets P are not passing through the fixing unit, which decreases the amount of energy used per unit time. This decreases the amount of energy supplied to the non-sheet passing region per unit time, which decreases the temperature relative to the other region.
Among the three conditions, the temperature difference between the center and the ends in the longitudinal direction is largest under condition C. The large temperature difference between the center and the ends in the longitudinal direction can cause the fixing film to be crinkled. Thus, the increased conveyance interval may disadvantageously cause a large temperature difference between the center and the ends in the longitudinal direction. In this embodiment, the ratio of power provided to the heating elements is controlled so that the temperature difference is prevented or minimized. Control of Power Ratio
In this embodiment, the ratio of power to be supplied to the heating elements is changed based on the conveyance interval. Table 5 shows the conveyance interval and the power ratio in zone 1.
In this embodiment, the power ratio for the heating element 54b1 is increased when the conveyance interval between the sheets P increases.
To ascertain the beneficial effects of this embodiment, printing was executed under the conditions shown in Table 4 and Table 5.
For condition A, since the conveyance interval was kept at 50 mm, the power ratio was also not changed. For condition B, since the conveyance interval was changed from 50 mm to 200 mm, the power ratio was changed from 7:3 to 8:2. For condition C, since the conveyance interval was changed from 50 mm to 400 mm, the power ratio was changed from 7:3 to 9:1. Changing the power ratio to increase the power ratio of the heating element 54b1 means that the amount of energy per unit time for the regions C in
Thus, changing the power ratio of the heating element 54b1 based on the conveyance interval can prevent or minimize an increase in the temperature difference between the center and the ends in the longitudinal direction of the fixing film even when throughput reduction in response to the detection results of the sub-thermistors 60 and 61 is performed.
Flowchart
In S104, the CPU 94 obtains the highest temperature from the detection results of the sub-thermistors 60 and 61. If the highest temperature is higher than 230° C., the process goes to S105, and if the highest temperature is less than 230° C., the process goes to S106. In S105, the CPU 94 sets the conveyance interval between the sheets P based on the highest temperature. The CPU 94 also sets the power ratio of the heating element 54b1 based on the highest temperature.
In S106, the CPU 94 determines whether to continue the printing. If the printing is to be continued, the process returns to S104, and if not, the process is terminated.
Thus, this embodiment changes the power ratio of the heating element 54b1 based on the conveyance interval between the sheets P. This allows preventing or minimizing an increase in the temperature difference between the center and the ends in the longitudinal direction of the fixing film.
The first embodiment describes control for increasing the conveyance interval between the sheets P in response to the detection results of the sub-thermistors 60 and 61 and increasing the power ratio of the heating element 54b1 based on the conveyance interval.
This embodiment describes control for decreasing the conveyance interval in response to the detection results of the sub-thermistors 60 and 61 and decreasing the power ratio of the heating element 54b1 based on the conveyance interval. The same reference signs are used for the components and configurations identical to those of the first embodiment, such as the image forming apparatus, the block diagram, the fixing unit, the heater, the fixing temperature sensor, the power control unit, power ratio control, prediction of the temperature of the fixing unit, and required power for each zone, and detailed descriptions here are omitted.
Initial Conveyance Interval
The first embodiment describes control for setting the initial conveyance interval as small as possible and increasing the conveyance interval in response to the detection results of the sub-thermistors. The second embodiment describes control for setting the initial conveyance interval as large as possible and decreasing the conveyance interval in response to the detection results of the sub-thermistors. The initial conveyance interval is set as large as possible on condition that the width of the sheets P specified by the user can be determined before the CPU 94 starts a printing operation. For example, if the sheets P are found to be narrow, increasing the initial conveyance interval can prevent or minimize an increase in the temperature at the ends. In other words, the possibility that relatively high temperatures are detected by the sub-thermistors 60 and 61 can be prevented or minimized. Setting the initial conveyance interval as large as possible is effective, for example, in preventing the fixing film or the pressure roller from becoming hot as much as possible.
However, setting the initial conveyance interval large causes throughput reduction, resulting in low production efficiency. For this reason, throughput increase control for decreasing the conveyance interval in response to the detection results of the sub-thermistors 60 and 61 is performed. This allows balancing temperature control and production efficiency.
Sub-Thermistor and Throughput Increase
Next, throughput increase control in response to the detection results of the sub-thermistors 60 and 61 will be described. The throughput increase refers to control for increasing the production efficiency, which is the number of sheets printed per unit time, by decreasing the conveyance interval between the sheets P.
The distance S3 shown in
For this reason, the initial conveyance interval is set large in advance based on the width of the sheets P. For example, for image formation on A6-size sheets P (105 mm in width), the initial conveyance interval is set to 600 mm. The conveyance interval is adjusted based on the highest temperatures of the sub-thermistors 60 and 61.
Table 6 shows the relationship between the highest temperatures detected by the sub-thermistors 60 and 61 and the conveyance interval between the sheets P. For example, if the highest temperature of the sub-thermistor is 235° C., it corresponds to Lv2, and the conveyance interval is decreased from 600 mm to 200 mm.
To illustrate the challenges in this embodiment, printing is performed under the condition shown in Table 7.
The zone in Table 7 indicates the degree of warming of the fixing unit 50 before printing. Zone 1 indicates that the fixing unit 50 is sufficiently cooled. In this state, continuous printing on 30 sheets P is performed. The power ratio was set to 10:0 in view of the balance of a decrease in the temperature of the longitudinal ends and an increase in the temperature of the non-sheet passing portion with reference to Table 5 in the first embodiment. The power supply is controlled so that the main thermistor 59 reads 210° C. Printing is started at an initial conveyance interval between the sheets P of 600 mm.
Since the initial conveyance interval is 600 mm, there is no increase in the temperature of the non-sheet passing portion of the fixing film.
In the first to fourth sheets P, the highest temperatures of the sub-thermistors 60 and 61 did not reach 220° C. Thus, the highest temperature corresponds to Lv3 with reference to Table 6, the conveyance interval was changed from 600 mm to 50 mm.
The change in the conveyance interval to 50 mm, as indicated by the dashed line in
Control of Power Ratio
In this embodiment, the ratio of power to be supplied to the heating elements is also changed based on the conveyance interval. Table 8 shows the conveyance interval and the power ratio in zone 1.
In this embodiment, the power ratio of the heating element 54b1 is controlled so that it is decreased when the conveyance interval between the sheets P decreases.
To ascertain the beneficial effects of this embodiment, printing was executed under condition D shown in Table 7 in control for changing the power ratio based on the conveyance interval in accordance with Table 8.
A comparison between the thin solid line and the dashed line in
Since the control in this embodiment decreases the power ratio of the heating element 54b1 when the conveyance interval decreases, an increase in the temperature of the non-sheet passing portions can be prevented or minimized even when the conveyance interval decreases.
Thus, changing the power ratio of the heating element 54b1 based on the conveyance interval allows preventing or minimizing an increase in the temperature difference between the center and the ends of the fixing film in the longitudinal direction even if throughput is increased. The change also allows for preventing or minimizing an increase in the temperature of the non-sheet passing portions of the fixing film.
Other Configurations
In the first and second embodiments, the conveyance interval is changed in response to the detection results of the sub-thermistors 60 and 61.
However, for example, even for a configuration of a fixing unit without the sub-thermistors, the conveyance interval can be changed based on the information on the difference between the longitudinal length of each heating element and the width of the sheet P and the count value indicating the number of sheets P passed. For example, when a certain number of sheets P narrower in width than the longitudinal length of the heating elements are passed, a prediction that the temperature of the non-sheet passing portions may exceed a predetermined temperature is made, and the conveyance interval is increased.
Even with such a fixing unit, when the conveyance interval is changed, the temperature profile in the longitudinal direction of the fixing film may change as in the first and second embodiments. For this reason, the power ratio of the heating element 54b1 is changed in response to a change in the conveyance interval, as in the first and second embodiments.
Embodiment(s) of the present disclosure can also be realized by a computer of a system or apparatus that reads out and executes computer executable instructions (e.g., one or more programs) recorded on a storage medium (which may also be referred to more fully as a ‘non-transitory computer-readable storage medium’) to perform the functions of one or more of the above-described embodiment(s) and/or that includes one or more circuits (e.g., application specific integrated circuit (ASIC)) for performing the functions of one or more of the above-described embodiment(s), and by a method performed by the computer of the system or apparatus by, for example, reading out and executing the computer executable instructions from the storage medium to perform the functions of one or more of the above-described embodiment(s) and/or controlling the one or more circuits to perform the functions of one or more of the above-described embodiment(s). The computer may comprise one or more processors (e.g., central processing unit (CPU), micro processing unit (MPU)) and may include a network of separate computers or separate processors to read out and execute the computer executable instructions. The computer executable instructions may be provided to the computer, for example, from a network or the storage medium. The storage medium may include, for example, one or more of a hard disk, a random-access memory (RAM), a read only memory (ROM), a storage of distributed computing systems, an optical disk (such as a compact disc (CD), digital versatile disc (DVD), or Blu-ray Disc (BD)™), a flash memory device, a memory card, and the like.
While the present disclosure has been described with reference to exemplary embodiments, it is to be understood that the disclosure is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2022-181542, filed Nov. 14, 2022, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2022-181542 | Nov 2022 | JP | national |