The present invention relates to an image forming apparatus which has a fixing device for fixing a toner image to recording medium.
In the field of an image forming apparatus such as a copying machine, a laser beam printer, etc., a thermal fixing device has long been known, which employs a ceramic heater (as its heat source), and an endless film through which the heat from the heat source is applied to a sheet of recording medium and a toner image thereon, to fix the toner image to the sheet of recording medium. The ceramic heater is made up of a ceramic substrate and a heat generating member formed on the substrate by printing. In an image forming operation, an unfixed image on a sheet of recording medium is heated though the film by the heater. As for the method for controlling the electric power supplied to the heat generating member, there are phase control, wave number control, hybrid control, etc. The hybrid control is a combination of the phase control and wave number control. The heater is controlled in temperature with the use of one of these controls. More concretely, the heating element of the heater is turned on or off while a sheet of recording medium is moved in contact, or virtually in contact, with the sheet of recording medium. Thus, some areas of the sheet of recording medium move past the heating element while the heating element is supplied with electric power, whereas the other areas are move past the heating element while the heating element is not supplied with electric power. In other words, some areas of the sheet of recording medium are heated by the heating element itself, whereas the other areas of the sheet of recording medium are not heated by the heating element itself. Thus, it is possible that after the fixation of the unfixed toner image to the sheet of recording medium, the resultant image will appear nonuniform in density (which hereafter may be referred to simply as “nonuniform fixation”). Generally speaking, wave number control and hybrid control are longer in control cycle than phase control. Therefore, in a case where the heater is supplied with electric power directly from a commercial electric power source (50 Hz or 60 Hz), the nonuniform fixation is likely to be more noticeable when wave number control or hybrid control is used to control the power supply to the heater than when phase control alone is used. Further, in a case where the heater is provided with two or more heating elements positioned in parallel in such a manner that the lengthwise direction of the heating elements become perpendicular to the direction in which recording medium is conveyed, the noticeablity of the nonuniform fixation is affected by the total amount of heat applied to a given point (area) of a sheet of recording medium and the toner image thereon, by the combination of the multiple heating elements. For example, in a case where the heater is provided with two heating elements, some areas of a sheet of recording medium may be heated by both heating elements, whereas the other areas of the sheet of recording medium may be heated by neither of the two heating elements, which results in the nonuniform fixation. The amount of difference in density between an area of a fixed image, which is high in density, and an area of the fixed image, which is low in density, and the periodicity of the nonuniformity, etc., of this nonuniformity in density attributable to nonuniform fixation is affected by the relationship among the distance between the adjacent two heating elements, recording medium conveyance speed, and method used for controlling the power supply to the heating elements. Thus, there has been proposed a method for optimally setting the distance between the adjacent two heating elements in order for a given area of a sheet of recording medium, which is heated by one of the two heating elements, not to be heated by the second heating element, and also, in order to heat the areas of the sheet of recording medium, which are not heated by one of the two heating elements, with the second heating element so that the sheet of recording medium becomes uniform in the amount of heat given thereto. For example, Japanese Laid-open Patent Application H05-333726 discloses a method for determining the optimal heating element interval for an apparatus having multiple (two) heating elements controlled by phase control or wave number control, according to the frequency of the AC power source and the recording medium speed of the apparatus.
However, if a fixing device is designed to use the method, disclosed in Japanese Laid-open Patent Application H05-333726, for minimizing a fixing apparatus in nonuniform fixation, the heating element interval is set based on the method used by the apparatus to control the amount by which its heating elements are supplied with electric power. The optimal heating element distance is affected by such factors as toner characteristic, heater substrate width, etc. Thus, using the above described method substantially reduces in latitude the fixing device in terms of design.
The present invention was made in view of the above described issues. Thus, the primary object of the present invention is to provide an image forming apparatus which can output a high quality image, more specifically, an image which is significantly less in nonuniformity attributable to fixation than any image outputted by an image forming apparatus in accordance with prior art.
Another object of the present invention is to provide an image forming apparatus which is significantly higher in latitude in terms of design than any image forming apparatus in accordance with the prior art.
According to an aspect of the present invention, there is provided an image forming apparatus comprising: an image forming station for forming an unfixed image on a recording material; a fixing portion for fixing an unfixed image formed on the recording material thereon, said fixing portion including an endless belt, a heater contacted to an inner surface of said endless belt, a back-up member forming a fixing nip for nipping and feeding the recording material together with said heater through said endless belt, said heater including a first heat generating element and a second heat generating element provided at a position downstream of said first heat generating element with respect to a feeding direction of the recording material; and an electric power control portion for controlling electric power supplied to said first heat generating element and said second heat generating element in accordance with a temperature of the fixing portion; wherein said electric power control portion supplies the electric power to said first heat generating element and said second heat generating element so that a feeding speed V1 of the recording material at the fixing nip, a distance A between said first heat generating element and said second heat generating element, a ratio Pin (%) of total electric power supplied to said first heat generating element and said second heat generating element set in accordance with the temperature of said fixing portion relative to maximum total electric power supplyable to said first heat generating element and said second heat generating element, a ratio E203(t) (%) of electric power supplied to said first heat generating element at timing t relative to the maximum total electric power, and a ratio E204(t) (%) of electric power supplied to said second heat generating element at timing t relative to the maximum total electric power, satisfy the following equation,
According to another aspect of the present invention, there is provided an image forming apparatus comprising an image forming station for forming an unfixed image on a recording material; a fixing portion for fixing an unfixed image formed on the recording material thereon, said fixing portion including an endless belt, a heater contacted to an inner surface of said endless belt, a back-up member forming a fixing nip for nipping and feeding the recording material together with said heater through said endless belt, said heater including a first heat generating element and a second heat generating element provided at a position downstream of said first heat generating element with respect to a feeding direction of the recording material; and an electric power control portion for controlling electric power supplied to said first heat generating element and said second heat generating element in accordance with a temperature of the fixing portion, said electric power control portion selecting an electric power level Pin (%) from a plurality of electric power levels in accordance with a temperature of the fixing portion, for each control cyclic period comprising a plurality of successive half-cycles of an AC waveform; wherein at least one electric power level of the plurality of electric power levels is set so that a feeding speed V1 of the recording material at the fixing nip, a distance A between said first heat generating element and said second heat generating element, a ratio E203(t) (%) of electric power supplied to said first heat generating element at timing t, and a ratio E204(t) (%) of electric power supplied to said second heat generating element at timing t, satisfy the following equation,
These and other objects, features, and advantages of the present invention will become more apparent upon consideration of the following description of the preferred embodiments of the present invention, taken in conjunction with the accompanying drawings.
a), 3(b), 3(c) and 3(d) are plan views of the ceramic heaters, one for one, with which the present invention is compatible, and shows the general structure of the heaters.
a) is a drawing of the zero-cross point detection circuit compatible with the present invention, and
a) and 12(b) are graphs which show the relationship between a given point of a sheet of recording medium in terms of the recording medium conveyance direction, and the amount of electric power (which is equivalent to the amount of heat given to the given point of the sheet of recording medium) supplied to the first and second heating elements while the given point was conveyed through the fixation nip in the second embodiment.
Hereafter, the embodiments of the present invention are described in detail with reference to the appended drawings. However, the measurement, material, and shape of the structural components in the following embodiments of the present invention, positional relationship among the structural components, etc., are to be altered as necessary according to the structure of the apparatus to which the present invention is applied, and various conditions under which the apparatus is to be operated. That is, the following embodiments of the present invention are not intended to limit the present invention in scope.
(General Structure of Image Forming Apparatus)
First, referring to
The image forming apparatus forms an image on a sheet of recording medium through the following steps. First, the peripheral surface of the photosensitive drum 109 is uniformly charged by the charge roller 106. Then, the uniformly charged portion of the peripheral surface of the photosensitive drum 109 is exposed by a scanner unit 111, which is an exposing means. More specifically, the scanner unit 111 contains a laser diode 112, a rotational polygon mirror 113, and a deflection mirror 114. As a beam of laser light is emitted from the laser diode 112, the beam is made to scan the uniformly charged portion of the peripheral surface of the photosensitive drum 109 in the direction (primary scan direction) which is perpendicular to the rotational direction of the photosensitive drum 109, by the polygon mirror 113 and deflection mirror 114, while being made to scan the uniformly charged portion of the peripheral surface of the photosensitive drum 109 in the direction (secondary scan direction) which is parallel to the rotational direction of the photosensitive drum 109, by the rotation of the photosensitive drum 109. Consequently, a two-dimensional latent image is effected on the peripheral surface of the photosensitive drum 109.
The latent image effected on the peripheral surface of the photosensitive drum 109 is developed into a visible image, that is, an image formed of toner, by the toner supplied by the development roller 107. Then, the toner image is transferred in the nip between a transfer roller 110 and photosensitive drum 109, onto the sheet of recording medium conveyed to the nip. Then, the sheet of recording medium, onto which the toner image has just been transferred, is conveyed to a fixing device 115 (fixation station). In the fixing device 115, the unfixed toner image on the sheet of recording medium is subjected to heat and pressure. Thus, the unfixed toner image becomes fixed to the sheet of recording medium. Thereafter, the sheet of recording medium is conveyed further by a pair of intermediary discharge roller 116. Then, it is discharged from the main assembly of the image forming apparatus, ending thereby the sequence for printing an image on the sheet of recording medium.
(General Structure of Fixing Device)
Next, referring to
Further, the fixing device 115 is provided with a ceramic heater 224 (heater) attached to the bottom surface (in
The ceramic heater 224 has a dielectric ceramic substrate 301 formed of SiC, AlN, Al2O3, or the like, and a pair of heating elements 203 (first heating element) and 204 (second heating element) formed on the dielectric substrate 301 by paste-printing or the like method. The two heating elements 203 and 204 extend in the lengthwise direction of the dielectric substrate 301. The surface of the heating element 203, which comes into contact with the heating sleeve 402, and the surface of the heating element 204, which comes into contact with the heating sleeve 402, are protected by a protective layer 302 formed of glass or the like substance. The opposite surface of the dielectric substrate 301 from the surface which has the heating elements 203 and 204 has a thermistor 222 as a temperature detection element. Further, the ceramic heater 224 is also provided with a thermistor 223 (
The heating elements 203 and 204 may be made so that they are uniform in electrical resistance value in terms of their lengthwise direction, or so that their center portions are different in electrical resistance value from their lengthwise end portions. For example, in a case where a small sheet of recording medium is to be heated, the lengthwise end portions of the heater 224 are outside the path of the sheet of recording medium, and therefore, are likely to become higher in temperature than the center portion of the heater 224. Thus, in order to keep the heater 224 uniform in temperature in terms of its lengthwise direction, the heating elements 203 and 204 may be made so that their lengthwise end portions are different in electrical resistance value from their center portion. Incidentally, a heater made so that its lengthwise end portions are different in electrical resistance value from its center portion is referred to as a “tapered heater”. Further, in order to make it easier for the heating sleeve 402 to slide on the heater 224, the interface between the heating sleeve 402 and ceramic heater 224 may be provided with grease or the like. Further, the heating elements 203 and 204 of the ceramic heater 224 may be on the opposite surface of the dielectric ceramic substrate 301 from the nip, instead of the surface of the dielectric ceramic substrate 303, which faces the nip.
In the case of the fixing device 115 of the heating film type, which was described above, the inward surface of the heating sleeve 402 directly contacts the ceramic heater 224. Therefore, the heat generated by the ceramic heater 224 is highly efficiently given to the fixation nip. Therefore, the fixing device 115 is very effective in that it can heat a toner image at a satisfactory temperature level, is smaller in power consumption, and is short in the length of startup time.
(Structure of Electric Power Supply Circuit)
Next, referring to
More specifically, the heating element 203 is driven by a triac 226, whereas the heating element 204 is driven by a triac 227. Referential codes 207 and 208 stand for the bias resistors for the triac 226. A referential code 209 stands for a photo-triac coupler for securing a proper amount of creepage distance between the primary and secondary sides of the electrical power source. As electric power is supplied to the light emitting diode of the photo-triac coupler 209, the triac 226 is turned on. A referential code 211 stands for a resistor for regulating the electric current which flows to the photo-triac coupler 209. A referential code 212 stands for a transistor for turning on or off the photo-triac coupler 209.
The transistor 212 reacts to a signal FSRD 1 sent thereto from an engine controller 220 by way of a resistor 213. The engine controller 220 is equivalent to an electric power controller capable of controlling the electric power to be supplied to the heating element 203, and the electric power to be supplied to the heating element 204, independently from each other. The signal FSRD1 is set to “high” when it is necessary for the transistor 212 to be turned on to turn on the photo-triac coupler 209. It is set to “low” when it is necessary for the transistor 212 to be turned off the photo-triac 209.
Referential codes 214 and 215 are bias resistors for the triac 227. A referential code 216 stands for a photo-triac coupler for securing a creepage distance between the primary and secondary sides of the electrical power source. As electric power is supplied to the light emitting diode of the photo-triac coupler 216, the triac 227 is turned on. A referential code 217 stands for a resistor for regulating the electric current which flows to the photo-triac coupler 216. A referential code 218 stands for a transistor for turning on or off the photo-triac coupler 216. The transistor 218 reacts to a signal FSRD2 sent thereto from the engine controller 220 by way of the resistor 219.
A referential code 221 stands for a zero-crossing point detection circuit which is in connection to the AC power source 201 by way of an AC filter 202. The zero-crossing point detection circuit 221 sends a pulse signal (which hereafter may be referred to as “zero-crossing point detection signal”) to the engine controller 220 to inform the engine controller that the AC power source voltage is no more than a threshold value. The engine controller 220 detects the edge of the zero-crossing point signal, and turns on or off the triacs 226 and 227 by phase control, wave number control, and/or hybrid control, which will be described later.
The referential code 222 stands for the thermistor for detecting the temperature of the heater 224. The thermistor 222 is positioned on the ceramic heater 224, with the placement of a dielectric member high enough in withstand voltage, between itself and the heating elements 203 and 204, in order to secure a sufficient amount of dielectric distance between the thermistor 222 and the heating elements 203 and 204. The thermistor 223 is for detecting the temperature of one of the lengthwise end portions of the ceramic heater 224. The thermistor 223 is positioned on the ceramic heater 224, with the placement of a dielectric member high enough in withstand voltage, between itself and the heating elements 203 and 204, in order to secure a sufficient amount of dielectric distance between itself and the heating elements 203 and 204.
The temperature detected by the thermistor 222 and the temperature detected by the thermistor 223 are detected as the partial voltage between the resistor 228 and thermistor 222, and the partial voltage between the resistor 229 and thermistor 223, respectively, and are inputted into the engine controller 220 after being converted from analog signal into a digital signal. The temperature of the ceramic heater 224 is monitored by the engine controller 220, and is compared with the temperature value stored in the engine controller 220, to calculate the amount by which electric power is to be supplied to the heating elements 203 and 204. The thus obtained amount by which electric power is to be supplied to the heating elements 203 and 204 is converted into the phase angle or wave number, according to which the engine controller 220 sends signals FSRD and FSRD2 to the transistors 212 and 218, respectively.
The signal FSRD1 is for driving the transistor 212 to make the photo-triac coupler 209 to emit light. The signal FSRD2 is for driving the transistor 218 to make the photo-triac coupler 216 emit light. Hereafter, the signals FSRD1 and FSRD2 may be referred to simply as FSRD1 and FSRD2, respectively. The amount by which electric power to be supplied to the heating element 203, and the amount by which electric power is to be supplied to the heating element 204, are controlled with the use of these FSRD1 and FSRD2. As described above, the first and second heating elements 203 and 204 can be independently controlled from each other, by the engine controller 220.
A referential code 225 stands for a motor used as a mechanical power source of the system for conveying a sheet of recording medium, and also, as mechanical power source for driving the photosensitive drum 109. The engine controller 220 detects the speed of the motor 225 by receiving a speed signal pulse (FG) sent from the motor 225. Further, the engine controller 220 compares the FG signal with the referential clock, and outputs an acceleration signal or a deceleration signal, based on the results of the comparison, to control the recording medium conveyance speed and process speed. Further, the engine controller 220 can issue a command to change the motor 225 in rotational speed in order to change the recording medium conveyance speed according to the size of a sheet of recording medium, or the like factor. In this embodiment, however, the motor 225 is not changed in rotational speed.
Next, referring to
The ceramic heater 224 shown in
(Phase Control and Wave Number Control)
The electric power supply to the heating elements 203 and 204 of the ceramic heater 224 is managed by a combination of phase control and wave number control. Here, phase control and wave number control are described.
Phase control is a method for turning on the ceramic heater 224 at the point in time which corresponds to a specific phase angle in half an oscillatory cycle (half cycle) of an AC power source to control the amount by which electric power is supplied to the ceramic heater 224. In the case of phase control, therefore, each control cycle is equivalent to one half the oscillatory cycle of the AC power. Thus, in phase control, electric current is flowed for every half the waveform. In other words, the electric current flowed by phase control is relatively small in the amount of change, and is short in the interval between the change. That is, phase control is relatively small in the amount of change to the voltage provided by the AC power source, which is attributable to the changes in the load current of electrical devices connected to the AC power source which is also in connection to an illumination device, and the impedance of the wiring. Therefore, phase control is advantageous from the standpoint of preventing the flickering of an illumination device. However, as a heater is turned on or off with the use of phase control, the amount by which electric current flows suddenly changes, which in turn generates high frequency electric current. Therefore, phase control is disadvantageous from the standpoint of minimizing the generation of high frequency electric current.
The wave number control is a method for turning a heater on or off for every half the oscillatory cycle of the AC power source, in order to control the amount by which electric power is supplied to the heater. In wave number control, therefore, the length of each control cycle is equal to the length of half the oscillatory cycle of the AC power supply. When the power supply to a heater is controlled by wave number control, the heater is turned on or off at a point in time which corresponds to the immediate adjacencies of the zero crossing point of the waveform of the AC power source, and therefore, high frequency electric current is unlikely to be generated. Therefore, from the standpoint of minimizing the generation of high frequency electric current, wave number control is advantageous to phase control. However, wave number control is greater in the change in current amount than phase control. Therefore, it is more likely to cause an illumination device to flicker than phase control.
From the standpoint of preventing the generation of high frequency electric current and switching noise, hybrid control, which is a combination of phase control and wave number control, is better than phase control alone. Further, it can control the flickering better than wave number control, and also, can control the power supplied to the heater, in a greater number of steps than wave number control alone. The hybrid control in this embodiment is described later in detail.
(Zero Crossing Point Detection Circuit and Waveform of Zero Crossing Signal)
a) shows the details of the zero-crossing point detection circuit 221.
A photo-coupler 509 is an element for securing a creepage distance between the primary and secondary sides. Resistors 508 and 510 are for limiting the current which flows to the photo-coupler 509. As the neutral side becomes higher in potential level than the hot side, the transistor 507 turns on. Therefore, the light emitting diode 509a in the photo-coupler 509 turns off, and the photo-transistor 509b turns off, causing thereby the output voltage of the photo-coupler 509 to be high.
On the other hand, if the neutral side becomes lower in potential level than the hot side, the transistor 507 turns off, causing thereby the light emitting diode 509a in the photo-coupler 509 to emit light. Thus, the photo-transistor 509b turns on, causing thereby the output voltage of the photo-coupler 509 to be low. That is, the zero crossing signal is a pulse signal which changes in potential level according to whether the potential level of the hot side is higher or lower by the amount equal to the threshold voltage Vz, than the potential level of the neutral side.
This output of the photo-coupler 509 is inputted, as a zero crossing point signal, to the engine controller 220 by way of a condenser 511. As the engine controller 220 receives the zero crossing point detection signal, it detects the rising and falling edges of the zero crossing point detection signal, and uses the detected edges as the trigger to turn on or off the triacs 226 and 227.
However, the threshold voltage Vz is not exactly zero in value. Therefore, the leading edge of the zero crossing point detection signal is slightly offset from the true zero crossing point, and so is the trailing edge. Therefore, if this zero crossing point detection signal is used as the trigger signal, without any modification, the length of time, which corresponds to the amount of deviation between the leading edge of the zero crossing point detection signal and the true zero crossing point, and between the trailing edge of the zero crossing point detection signal and the true zero crossing point, becomes the phase deviation attributable to the positivity and negativity of the input power source. Therefore, the engine controller 220 detects the length of the oscillatory cycle (2T) of the trailing edge of the zero crossing point detection signal, and calculates half (T) the length of the oscillatory cycle (2T). Then, it creates a pseudo leading edge within a length T of time, in itself. Hereafter, a combination of the trailing edge and the pseudo leading edge is referred to as “control zero crossing signal edge”. The engine controller 220 uses this control zero crossing point detection signal, as the trigger signal for controlling the triacs.
(Hybrid Control)
Next, referring to
The waveform of the FSRD1 and the waveform of the FSRD2 are the waveforms of the FSRD1 and FSRD2 outputted by the engine controller 220 described referring to
The waveform of the electric current which flows to the heating elements 203 and 204 while being controlled by the FSRD1 and FSRD2, respectively, are reflected upon the waveform of the electric current which flows through the heating element 203, and the waveform of the electric current which flows through the heating element 204, respectively. In this embodiment, the heating elements 203 and 204 are different in the amount of resistance. Therefore, the electric current which flows through the heating element 203, and the electric current which flows through the heating element 204, are different in the amplitude of waveform. The heating element current waveform (uppermost waveform in
(Pattern of Electric Power Control)
Next, referring to
A referential code P203(t) stands for the ratio of the amount by which electric power is to be supplied to the first heating element 203, relative to the maximum amount of electric power which can be supplied to the first heating element 203, in a length of time which corresponds to half the oscillatory cycle of the commercial AC power source (which is equivalent to 10 msec, if electric power source frequency is 50 Hz). A referential code E203(t) stands for the ratio of the amount by which electric power is to be supplied to the first heating element 203, relative to the “maximum amount by which electric power can be supplied to the combination of the first and second heating elements 203 and 204”.
Similarly, a referential code P204(t) stands for the ratio of the amount by which electric power is to be supplied to the second heating element 204, relative to the maximum amount by which electric power can be supplied to the second heating element 204, per half the cycle. A referential code E204(t) stands for the ratio of the amount by which electric power is to be supplied to the second heating element 204, relative to the “maximum amount by which electrical power can be supplied to the combination of the first and second heating elements 203 and 204”, per half the cycle.
Referential codes t1-t8 stand for points in time. For example, E203(t1) and E204(t1) stand for the ratios of the amount by which electric power is to be supplied to the heating elements 203 and 204, respectively, relative to the maximum amount by which electric power can be supplied to the combination of the heating elements 203 and 204, at the same point (t1) in time (at the same point in phase).
In this embodiment, each cell (half cycle period) of two rows P203(t) and P204(t) of the table in
The row E203(t) and E204(t) of the table in
(Method for Creating Control Pattern (Electric Power Supply Table))
At this time, a method for creating the pattern in which the amount by which electric power is to be supplied to the heater 224 in a case where the heater 224 is configured in its heating element arrangement as shown in
The left side of Formula (3) is the sum of the ratio (%) of the amount by which electric power is to be supplied to the heating element 203 at a give point t in time, and the ratio (%) of the amount by which electric power is to be supplied to the heating element 204, (A/V1) after the given point t in time. In the formula (3), “A” in Formula (3) stands for the distance between the heating elements 203 and 204, “V1” stands for the recording medium conveyance speed in the fixation nip. That is, “E203(t)” is the ratio of the amount by which electric power is to be supplied to the heating element 203 with the first timing (point t in time) per control cycle. “E204(t)” is the ratio of the amount by which electric power is to be supplied to the heating element 204 with the second timing (point (t+A/V1) in time) per control cycle. The right side of Formula (3) is the sum of E203(t) and E204 (t+A/V1). On the other hand, as described above, the right side indicates the ratio of the target total amount by which electric power is to be supplied to the combination of the two heating elements 203 and 204, relative to the total amount by which electric power can be supplied to the combination of the heating elements 203 and 204, per control cycle. That is, it is the ratio that is to be changed (switched) according to the temperature detected by the thermistor 222 during a printing operation. Incidentally, “≈” means “approximately equal”. A given point Y of a sheet of recording medium travels between the first and second heating elements in the length (A/V1) of time. The point Y of the sheet of recording medium is heated at a point t1 in time, by the heat from the first heating element, the amount of which is equivalent to E203(t), and then, is heated at a point (t+A/V1) in time, by the heat from the second heating element, the amount of which is equivalent to E204(t+A/V1). Therefore, if the length (A/V1) of time is equivalent to half the oscillatory cycle of the AC power source, what is desirable to minimize the fixing device 224 in nonuniform fixation is to create the electric power table (control pattern) so that the sum of E203(t1) and E204(t2) becomes roughly equal to the electric power level Pin. In such a case, the table is desired to be created so that the sum of the E203(t2) and E204(t3) becomes roughly equal to Pin, and the sum of E203(t3) and E204(t4) also becomes roughly equal to Pin. This is also true with other points in phase angle.
In this embodiment, P203(t) and P204(t) were set to satisfy Formulas (1)-(3) when the recording conveyance speed V1 is 200 mm/sec; the distance A between the heating elements 203 and 204 is 2 mm; R203 is 17Ω; R204 is 27Ω; and the AC power source frequency is 50 Hz. The P203(t) and P204(t) are to be set with 2.5% interval, and the negative and positive currents are made symmetrical in waveform. Therefore, what is desirable is set the control pattern so that the value of the left side of the equation (3) become as close as possible to the value of Pin (which is electric power ratio selected in response to detected temperature), while taking the effects of the high frequency current and/or flickering; it is unnecessary for the value of the left side of Equation (3) to become exactly equal to the value of Pin.
in which n is an integer.
Even if the length of time it takes for the point Y to travel the distance A between the two heating elements 203 and 204 at the recording conveyance speed V1 is different from the length of time equivalent to half the cycle (waveform) of the AC power source, Formula (4) was used for the calculation as long as the difference is within the rated wave number of the AC power source.
For example, P203(t1) is 50%. Therefore, the ratio at which heat is generated by the heating element 203 (amount by which electric power is to be supplied to heating element 203) is 30.8%, which is obtained from Equation (1). The ratio at which electric power is to be supplied to the heating element 204 at point t2 in time, that is, A/V1 seconds after electric power begins to be supplied to the heating element 203, is only 19.32% (=50%-30.68%) which is obtained from Formula (3). By converting these figures, P204(t2) is set to 50%, which is the smallest in the amount of error, with 2.5% interval. That is, referring to
Looking at other points in time, which correspond to other points in the oscillatory phase of the AC power source, E203(t3)+E204(t4), and E203(t6)+E204(t7) are both 50%. whereas the E203(t2)+E204(t3), and E203(t7)+E204(t8) are both 38.6(%). Further, E203(t4)+E204(t5) and E203(t5)+E204(t6) are both 61.36(%). In other words, at some points in oscillatory phase of the AC power source, the sum is different from 50%. However, the difference is no more than 20 points. As long as the difference is at this level, nonuniform fixation can be kept at or below the discernable level.
This embodiment was described with reference to the case in which Pin was 50%. However, even if Pin is not 50% as shown in
What is desirable to minimize the nonuniform fixation is to ensure that Formula (3) is satisfied at no less than 70% of time per control cycle. Further, when Pin is in a range of 30%-80%, the waveform of the electric power supplied to the heater 224 is fixation. Therefore, the tables, which is to be set to satisfy Formula (3), is desired to be set also to satisfy: 30%≦Pin≦80%.
Further, in a case where an image forming apparatus (fixing device) is enabled to convey a sheet of recording medium not only at the speed V1, but also, at speed V2, what is desirable is to control the power supply so that Formula (3) is satisfied when the sheet is conveyed at one of the two speeds, for example V1 (when speed is V2, V1 in Formula (3) is to be substituted by V2).
In this embodiment, P203(t1)-P204(t8) were obtained based on the control pattern (first control pattern) for the heating element 203, as described above. Needless to say, it may be set up so that the control pattern for the heating element 204 is first set, and then, the control pattern for the heating element 203 is set based on the control pattern for the heating element 204.
Next, referring to
Next, referring to
As described above, if a control pattern which satisfies Formula (3) is set in advance, and the heating elements are controlled based the control pattern which satisfies Formula (3), the fixing device 224 is minimized in the nonuniformity in which it applies heat to a sheet of recording medium.
Next, the second embodiment of the present invention is described. The image forming apparatus in this embodiment is the same in structure as the image forming apparatus in the first embodiment. Only difference in structure between the image forming apparatus in the second embodiment and that in the first embodiment is that the one in the second embodiment can be set in recording medium speed to V1 and V2. In the first embodiment described above, even if the image forming apparatus is provided with multiple recording medium conveyance speeds, the amount by which electric power is supplied to its heater is controlled with the use of only a single control pattern (electric power table). For example, in a case where the difference among the multiple recording medium conveyance speeds is minute, images which are uniform in density can be outputted with the use of only a single control pattern. In other word, the first embodiment is suitable for such a case. In comparison, in the second embodiment, the fact that the image forming apparatus can be operated at any of multiple recording medium speeds is taken into consideration, and multiple control patterns which are suitable for the multiple recording medium conveyance speeds, one for one, are prepared in advance, so that if the image forming apparatus is changed in its recording medium conveyance speed, the control pattern also can be changed to be matched to the new recording medium conveyance speed.
The mathematical formula in this embodiment, which is related to the recording medium conveyance speed V1, is the same as Formula (3). When the recording medium conveyance speed is set to V2, P203(t) and P204(t) have only to be set so that the following Formula (5) is satisfied:
In this embodiment, the first and second electric power tables for the recording medium conveyance speeds V1 and V2, which can satisfy Formula (3), when the recording medium conveyance speeds V1 and V2 are 200 mm/sec and 100 mm/sec, respectively; the distance A is 2 mm; R203 and R204 are 17Ω and 27Ω, respectively; and the frequency of the AC power source is 50 Hz, are created.
For example, in the case of the control table shown in
Next, referring to
Next, referring to
As is evident from the description of the second embodiment given above, even in the case of an image forming apparatus provided with two recording medium conveyance speeds, as long as the heating elements of the fixing device of the apparatus are controlled in the amount by which electric power is supplied thereto, in the pattern set in advance to satisfy both Formulas (3) and (5), according to each of the two recording medium conveyance speeds, the apparatus (fixing device) can be minimized in the nonuniform heat distribution across a sheet of recording medium. This embodiment was described with reference to the image forming apparatus provided with two recording medium conveyance speeds. However, it is not intended to limit the present invention in terms of the number of recording medium speeds with which an image forming apparatus is provided. That is, the present invention is also applicable to an image forming apparatus provided with two or more recording medium conveyance speed, as long as multiple control patterns which are suitable for the multiple recording conveyance speeds, one for one, are prepared, and the apparatus is switched in control pattern according to the selected recording medium conveyance speed. The effects of the application of the present invention to such an image forming apparatus are the same as those described above.
The structure of the image forming apparatus in this embodiment is roughly the same as that in the first embodiment described above, except that the heater of the fixing device of the apparatus in this embodiment is provided with three heating elements configured as shown in
In order to minimize the nonuniform fixation, the sum of the ratios by which electric power is supplied to the heating elements 203, 204 and 205 satisfies the following Formula (10).
It is assumed here that a sheet of recording medium is conveyed at a preset recording conveyance speed V1, and also that the given point Y of the sheet is given heat by the heating element 203 at points t in time; is given heat by the heating element 204, (A/V1) after the point t in time; and is given heat by the heating element 205, (B/V1) after when the point Y begins to be given heat by the heating element 204. “B” in Formula (10) stands for the distance between the heating elements 204 and 205. The left side of Formula (10) is the sum of the ratios by which electric power is supplied to the heating elements 203, 204, and 205, respectively. As for the right side of Formula (10), it is the ratio of the total amount by which electric power is supplied to the combination of the heating elements 203, 204 and 205, as it is in the first embodiment. That is, it is the ratio of the total amount of electricity, which is to be switched according to the temperature level detected by the thermistor 222 during a printing operation. Like in the second embodiment, if the image forming apparatus is provided with two recording medium conveyance speed V1 and V2, the electric power supply tables are to be set with the use of Formulas (10) and (11).
In this embodiment, the recording medium speed V1 was 200 mm/sec. The distance A between the heating elements 203 and 204 was 2 mm, and the distance B between the heating elements 204 and 205 was also 2 mm. R203, R204, and R205 were 30Ω, 20Ω and 10Ω, respectively. The AC power source frequency was 50 Hz. P203(t), P204(t), and P205(t) were set to satisfy Formula (10) under the above described conditions. Further, P203(t), P204(t) and P205(t) were also set to satisfy Formula (10) under the above described conditions, except that the recording medium conveyance speed was V2, which was 100 mm/sec. In other words, two control patterns (electric power tables) were independently set according to the two recording medium conveyance speeds V1 and V2, one for one. P203(t), P204(t) and P205(t) were set with 2.5% interval, and also that the electric current flowed through all heating elements become symmetrical in waveform in terms of the negative and positive sides. Therefore, it is possible that the left side of Formula (10) and the left side of Formula (II) do not become equal to Pin. Even in such a case, what is desirable to set the control pattern so that the difference between the left side of Formula (10) and Pin, and that between the left side of Formula (II) and Pin, are minimized. Further, the control patterns are to be set so that the differences are minimized, while taking into consideration the effects of the minimization upon the generation of the high frequency wave and/or flickering.
That is, the control patterns were set so that the following Formula was satisfied:
E203(tn)+E204(tn+1)+E205(tn+2)≅Pin
Even in a case where the length of time it took for a given point Y of a sheet of recording medium to travel across the distance A between the heating elements 203 and 204 was different from the length of time which is equivalent to half the waveform of the AC power source, Formula (10) was used for the calculation. For example, P203(t1) and P204(t2) were 50% and 0%, respectively. The values of E203(t1) and E204(t2) obtained using Formulas (7) and (8) were 9.09% and 0%, respectively. Thus, the ratio by which electric power begins to be supplied to the heating element 205 at a point t3 in time, that is, B/V1 seconds after the point t1 in time, was 40.91% from Formula (10). Converting this figure, P205(t3) was 70%, which was the smallest in error, with 2.5% interval. As described above, P204(t1)-P204(t8), and P205(t1)-P205(t8), were obtained based on the control pattern for the heating element 203. Needless to say, it may be for any of the three heating elements that a control pattern is first set.
b) shows an example of the actual control pattern used when the recording medium conveyance speed was V2. The length of time it takes for the point Y of the sheet of recording medium to travel between the heating elements 203 and 204 under the above described condition is 20 msec. Thus, the following Formula (13) was applied to Formula (II) to set the control patterns for the heating elements 204 and 205.
That is, the control patterns for the heating elements 204 and 205 were set to satisfy the following Formula:
E203(tn)+E204(tn+2)+E205(tn+4)≅Pin
The method for setting the control pattern for the heating elements 204 and 205 by calculation is the same as the above described on, and therefor, is not described in detail.
Next, referring to
The flowchart of the control sequence in this embodiment is the same as the one shown in
As described above, even an image forming apparatus (fixing device) having three or more heating elements can output a print which is virtually free of nonuniform fixation, as long as each of the three or more heaters is controlled according to the control pattern set to satisfy Formulas (10) and (11).
The structure of the image forming apparatus in this embodiment is the same as that of the image forming apparatus in the first embodiment, except that the heater of the fixing device of the apparatus in this embodiment is provided with three heating elements which branch as shown in
In order for the image forming apparatus (fixing device) structure as described, to be minimized in nonuniform fixation, the total amount by which electric power is supplied to the heater while a given point (Y) of a sheet of recording medium is conveyed through the fixation nip has to satisfy the following Formula (14).
A sheet of recording medium is conveyed at a preset speed V1, and a given point Y of the sheet of recording medium is given heat by the upstream heating element 203 at a given point t in time. Then, the point Y travels the distance A between the upstream heating element 203 and the heating element 204. Then, it is given heat by the heating element 204. The left side of Formula (14) is the sum of the amount of electric power, which is equivalent to the amount of heat given to the point Y by the upstream heating element 203, the amount of electric power, which is equivalent to the amount of heat given to the point Y by the heating element 204, and the amount of electricity which is equivalent to the amount of heat given to the point Y by the downstream heating element 203. The heating element 203 was made to branch in such a manner that the ratio in electrical resistance between the upstream and downstream heating elements 203 and 203 became 1:1. The right side of Formula (14) is the ratio by which electric power is supplied to the three heating elements per control cycle, like the one in the first embodiment, that is, the ratio of the total amount of electric power which is to be switch according to the temperature level detected by the thermistor during an image forming operation. Further, in a case where the image forming apparatus is provided with two or more recording medium conveyance speeds, the following Formula (15) is used in combination with Formula (14):
In this embodiment, the recording medium conveyance speed V1 was 200 mm/sec, and the distance A between the heating elements 203 and 204 was 2 mm. The distance B between the heating element 204 and the downstream heating element 3 was 2 mm. Further, R203 and R204 were 17Ω and 27Ω, respective. The frequency of the commercial electric power source was 50 Hz. That is, the specification of the apparatus and the condition under which the apparatus was operated were the same as those in the second embodiment. P203(t) and P204(t) were set so that Formula (14) was satisfied under the above described condition. Further, also in a case where the recording conveyance speed V2 was set to 100 mm/sec, the P203(t) and P204(t) were set so that Formula (14) was satisfied. In other words, the control pattern was set according to the recording medium conveyance speed. The P203(t) and P204(t) were set with 2.5% interval, so that the positive and negative sides of the combination of the electric currents which flow through the three heating elements, one for one, become symmetrical in waveform. Therefore, all that is necessary is to set the control tables to minimize the difference between the left and the right (Pin) sides of Formula (14) and the difference between the left and right (Pin) sides of Formula (15); it is not mandatory that the left side of Formula (14) and the left side of Formula (15) become equal to the amount (ratio) Pin by which heater is to be supplied with electric power.
That is,
Even if the length of time it takes for the point Y of a sheet of recording medium travel the distance A between the upstream heating element 203, or the distance B between the heating element 204 and the downstream heating element 203, is different from the length of time equivalent to half the cycle (half waveform) of the AC power source, Formula (14) may be used, as long as the difference is within the length of time equivalent to the rated frequency of the AC power source.
For example, P203(t1) and P204(t1) are both 50%. Thus, (E203(t1)/2+E204(t3)/2), which is the ratio by which heat is to be generated by the heating element 203 (by which electric power is to be supplied to heating element 203) is 30.68%, which is obtainable from Formula (I). The ratio by which electric power is to be supplied to the heating element 204 at a point t2 in time, that is, A/V1 seconds after the point t1 in time, has only to be 19.32%, which is obtainable from Formula (14). Converting this figure, P204(t2) was set to 50%, which is minimum in error, with the interval being 2.5%. As described above, P204(t1)-P204(t8) were obtained based on the control pattern for the heating element 203. Obviously, the heating element 204 may be the first heating element for which the control pattern is set. In such a case, the control pattern for the heating element 203 is set (by calculation) according to the control pattern for the heating element 204.
b) shows an example of the control pattern to be used when the recording medium conveyance speed is V2. The length of time it takes of the point Y of a sheet of recording medium to travel between the upstream heating element 203 and the downstream heating element 203 under the above-described condition is 20 msec. Thus, the calculation was made by applying Formula (13) to Formula (15) as in the third embodiment.
That is, the calculation was made so that the following formula was satisfied:
The method for setting the control pattern for the heating element 204 by calculation, is the same as the above described one, and therefore, is not described in detail.
Next, referring to
As described above, the present invention can enable even an image forming apparatus (fixing device), one of the multiple (two) heating elements of which bifurcates as if the heater of its fixing device has three heating elements, to output a print (image) which is virtually free of nonuniform fixation.
The structure of the image forming apparatus in this embodiment is the same as that of the image forming apparatus in the first embodiment, although the electric power supply to the heater of the fixing device of this apparatus is not switched in the control pattern (electric power table) even after the apparatus is switched in the recording medium conveyance speed. The structure of the heater in this embodiment is the same that in the fourth embodiment, which is shown in
In order to make the image forming apparatus in this embodiment virtually free of nonuniform fixation, the electric power table has to be set so that the total amount by which the heater is supplied with electric power satisfy both Formula (14) and (15), as in the above described fourth embodiment.
For example, when the recording medium conveyance speed is V1, P203(t) and P203(t5) are 0% and 100%. Therefore, E203(t3)/2+E203(t5)/2 is 30.68%. Thus, the ratio of the amount by which electric power is given to the heating element 204 at a point t in time, that is, A/V1 seconds after the point in time at which electric power begins to be supplied to the upstream heating element 203, is 19.32% (=50%-30.68%). Converting this figure into amount of electric power, E204(t4) is desired to be 50%, which is smallest in error, measured in a unit (interval) of 2.5%. On the other hand, when the recording medium conveyance speed is V2, E203(t2)/2+E203(t6)/2 is 15.34%. Therefore, in order for Pin to be 50%, E204(t4) has to be 34.66%. Converting this figure, the ratio of the electric power is 90%, which is the smallest I error, with unit of measurement being 2.5%. Here, P204(t4) was set to 70%, which is between 50% and 90%, in order to assure that even if the recording medium conveyance speed is switched from V1 to V2, this embodiment remains effective to prevent the nonuniform fixation. As described above, P204(t1-P204(t8) were obtained based on the control pattern for the heating element 203. Needless to say, the control pattern for the heating element 204 may be the first control pattern to be set, so that the control pattern for the heating element 203 can be set according to the control pattern for the heating element 204.
Next, referring to
The flowchart of the electric power supply control sequence in this embodiment is the same as that shown in
As is evident from the description of this embodiment given above, this embodiment is effective to significantly reduce an image forming apparatus provided with multiple recording conveyance speeds, in the nonuniform fixation, with the use of only one control pattern.
The preceding embodiments of the present invention may be used in combination, as long as the combination does not have adverse effects.
While the invention has been described with reference to the structures disclosed herein, it is not confined to the details set forth, and this application is intended to cover such modifications or changes as may come within the purposes of the improvements or the scope of the following claims.
This application claims priority from Japanese Patent Applications Nos. 125023/2012 and 094192/2013 filed May 31, 2012 and Apr. 26, 2013, respectively which are hereby incorporated by reference.
Number | Date | Country | Kind |
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2012-125023 | May 2012 | JP | national |
2013-094192 | Apr 2013 | JP | national |
Number | Name | Date | Kind |
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8200113 | Takami | Jun 2012 | B2 |
8744296 | Fukuzawa et al. | Jun 2014 | B2 |
20120155905 | Ogura | Jun 2012 | A1 |
Number | Date | Country |
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5-333726 | Dec 1993 | JP |
Number | Date | Country | |
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20130322908 A1 | Dec 2013 | US |