The present invention relates to an image forming apparatus using an electrophotographic process.
In recent years, also in the image forming apparatus using the electrophotographic process, there is a tendency that electric power consumed by a fixing device is increased with speed-up and diversification of options, and thus the capacity of a low-voltage power source portion is increased. In such a situation, in order to lower the maximum current consumption by increasing the power factor of the low-voltage power source portion, e.g., as described in Japanese Laid-Open Patent Application (JP-A) 2006-304534, there is an increasing use of a switching power source in which a power factor improving circuit such as a step-up active filler, is mounted.
However, the power factor improving circuit has a complicated circuit structure, and thus leads to an increase in the cost of the low-voltage power source portion, and due to an increase in the circuit, a large space is needed for providing the low-voltage power source portion. For this reason, it has been desired that the power factor is improved.
The present invention has been accomplished in the above-described situation. A principal object of the present invention is to provide an image forming apparatus capable of improving the power factor while reducing the cost of the apparatus.
According to an aspect of the present invention, there is provided an image forming apparatus comprising: a power source portion for converting an AC voltage of a commercial power source into a DC voltage; and a fixing portion for heating and fixing an image, formed on a recording material, on the recording material. The fixing portion includes a first heat generating element which generates heat by electric power supplied from the commercial power source and a second heat generating element which is controlled independently of the first heat generating element and which generates the heat by the electric power supplied from the commercial power source. The apparatus also includes a controller for controlling the electric power supplied to the first and second heat generating elements. When a plurality of periods of an AC waveform of the commercial power source constitute one control period, the controller sets a waveform of a current to be passed through each of the first and second heat generating elements in the one control period so that total electric power supplied to the first and second heat generating elements in the one control period is dependent on a temperature of the fixing portion. The controller sets the waveform of the current to be passed through each of the first and second heat generating elements so that, in an equiphase half wave in at least a part of the one control period, the current passes through one of the first and second heat generating elements from a halfway point of the half wave and the current passes through or does not pass through the other heat generating element throughout a period of the half wave. The controller sets a current supply starting timing of the current passing through the one of the first and second heat generating elements from the halfway point of the half wave, at timing when a current passing toward the power source portion stops.
According to another aspect of the present invention, there is provided an image forming apparatus comprising: a fixing portion for heating and fixing an image, formed on a recording material, on the recording material. The fixing portion includes a first heat generating element which generates heat by electric power supplied from the commercial power source and a second heat generating element which is controlled independently of the first heat generating element and which generates the heat by the electric power supplied from the commercial power source. The apparatus also includes a controller for controlling the electric power supplied to the first and second heat generating elements. The controller switches a rule of a waveform of an AC current to be passed through each of the first and second heat generating elements depending on a duty ratio of total electric power supplied to the first and second heat generating elements.
According to a further aspect of the present invention, there is provided an image forming apparatus comprising: a power source portion for converting an AC voltage of a commercial power source into a DC voltage; and a fixing portion for heating and fixing an image, formed on a recording material, on the recording material. The fixing portion includes a first heat generating element which generates heat by electric power supplied from the commercial power source and a second heat generating element which is controlled independently of the first heat generating element and which generates the heat by the electric power supplied from the commercial power source.
The apparatus also includes: a current detecting portion for detecting a resultant current passing through the power source portion and the first and second heat generating elements; and a controller for controlling the electric power supplied to the first and second heat generating elements. The controller sets the length of the one control period depending on a detected current of the current detecting portion.
These and other objects, features and advantages of the present invention will become more apparent upon a consideration of the following description of the preferred embodiments of the present invention taken in conjunction with the accompanying drawings.
In
In
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In
With reference to the drawings, embodiments for carrying out the present invention will be specifically described below. However, the dimensions, the materials, the shapes and the relative arrangement of constituent elements described in the following embodiments should be appropriately changed depending on structure and various conditions of devices (apparatuses) to which the present invention is to be applied. That is, the scope of the present invention is not intended to be limited to the following embodiments.
In the neighborhood of a cassette 22 for accommodating a sheet 21 as a recording material (medium), a sheet presence/absence detecting sensor 24 for detecting the presence or absence of the sheet 21 in the cassette 22 is provided. Further, in a feeding path of the sheet 21, a sheet feeding roller 25, separation rollers 26a and 26b and a register roller pair 27 are provided, and in the neighborhood of the register roller pair 27, downstream thereof with respect to a sheet feeding direction, a register sensor 28 is provided. Further downstream in the feeding path with respect to the sheet feeding direction, a secondary transfer roller 29 is provided in contact with the intermediary transfer belt 19, and a fixing device 30 is provided downstream of the secondary transfer roller 29.
A controller 31 as a control portion of the image forming apparatus is constituted by a CPU (central processing unit) 32 including ROM 32a, RAM 32b, a timer 31 and the like, and by various input/output control circuits (not shown) and the like.
Next, the electrophotographic process will be briefly described. Surfaces of the photosensitive drums 13 are electrically charged uniformly by the charging rollers 15. Then, the surfaces of the photosensitive drums 13 are irradiated, by the laser scanners 11, with laser light modulated depending on image data. Electric charges at a portion where the photosensitive drum is irradiated with the laser light are removed, so that electrostatic latent images are formed on the surfaces of the photosensitive drums 13. As a result, the respective color toner images are formed on the surfaces of the photosensitive drums 13.
The toner images formed on the photosensitive drums 13 are attracted toward the intermediary transfer belt 19 at nips between the intermediary transfer belt 19 and the respective photosensitive drums 13 by the primary transfer rollers 18 to which a primary transfer voltage is applied. Then, the respective color toner images are successively transferred onto the intermediary transfer belt 19, so that a full-color image is finally formed on the intermediary transfer belt 19.
On the other hand, the sheet 21 in the cassette 22 is fed by the sheet feeding roller 25, and then by the separation rollers 26a and 26b, the sheet 21 is passed through the register roller pair 27 one by one and then is conveyed to the secondary transfer roller 29. At a nip between the intermediary transfer belt 19 and the secondary transfer roller 29 disposed downstream of the register roller pair 28, the toner image is transferred from the intermediary transfer belt 19 onto the sheet 21. Finally, the toner image on the sheet 21 is heat-fixed by the fixing device 30 as a heating portion, and the sheet 21 is discharged to an outside of the image forming apparatus.
[Fixing Device]
The pressing roller 103 is rotationally driven, by an unshown driving motor or the like as a driving means, in the counterclockwise direction indicated by an arrow in
A temperature of the heater 100 is increased up to a predetermined temperature (control target temperature) by supplying electric power to the heater 100, and then temperature control is effected for maintaining the heater temperature at the predetermined temperature. In this temperature-controlled state, the sheet 21 on which an unfixed toner image T is carried is fed in a sheet feeding direction (leftward direction in (b) of
A chain line shown in
[Heater Driving Circuit]
In
In the image forming apparatus, in the primary side of the electric power supplying circuit, a constitution in which the heat generating elements 111 and 112 of the fixing device 30 and a power source unit (power source portion) 53 for supplying the electric power to the secondary side are directly connected with the commercial power source to be supplied with the electric power is employed. Further, in the secondary side of the electric power supplying circuit, a constitution in which the motor and units, to be operated during image formation, such as the motor for rotating the photosensitive drums 13 and the intermediary transfer belt 19, and the laser scanners 11 and the like are connected with the commercial power source in the non-contact manner to be supplied with the electric power is employed.
The heat generating elements 111 and 112 are driven by triac driving circuits 60 and 70. A temperature detecting element 54 provided on the back surface of the heater is connected to the ground at one end thereof and is connected to a resistor 55 at another end thereof, and is further connected to an analog input port AN0 of the CPU 32 via a resistor 56. The temperature detecting element 54 has a property that a resistance value is lowered when a temperature thereof is high. The CPU 32 detects the temperature of the heater 100 by converting information on an inputted voltage value into a temperature on the basis of a temperature table (not shown) preset from a divided voltage of the temperature detecting element and the resistor 55.
An AC waveform supplied from the commercial power source 50 is detected by a zero-cross generating circuit 57 via the AC filter 52. The zero-cross generating circuit 57 has a constitution in which a high level signal is outputted when a voltage of a commercial power source 50 is not more than a threshold voltage in the neighborhood of 0 V, and a low level signal is outputted in other cases. Then, into an input port PA1 of the CPU 32, a pulse signal with a period substantially equal to a period of the commercial power source 50 is inputted via a resistor 58. The pulse signal outputted from the zero-cross generating circuit 57 to the CPU 32 is a zero-cross signal (“ZEROX”). The CPU 32 detects an edge where a zero-cross signal is changed from the high level to the low level, and use the detected edge in control of the heater.
The CPU 32 determines the ON-timing when the triac driving circuits 60 and 70 are driven on the basis of the temperature detected by the temperature detecting element 54, and then outputs driving signals Drive 1 and Drive 2. First, the triac driving circuit 60 as a first driving circuit for supplying and blocking the electric power to the heat generating element 111 will be described. During the heater ON-timing, depending on the detected temperature, when the CPU 32 outputs the high level signal from an output port PA21, the high level signal is inputted into a base of a transistor 65 via a base resistor 67, so that the transistor 65 is turned on. When the transistor 65 is turned on, a photo-triac coupler 62 is in an ON state. Incidentally, the photo-triac coupler 62 is a device for ensuring a creepage distance between the primary side and the secondary side, and a resistor 66 is a resistor for limiting a current passing through a light-emitting diode in the photo-triac coupler 62.
Resistors 63 and 64 are bias resistors for a bi-directional thyristor (triac) 61, and the triac 61 is in an electric conduction state by turning on the photo-triac coupler 62. The triac 61 is an element held, when an ON-trigger functions during the electric power supply from the commercial power source 50, in the electric conduction state until the AC voltage becomes zero volts. As a result, the electric power depending on the ON-timing of the triac 61 is to be supplied to the first heat generating member 111.
A constitution of the triac driving circuit 70 as a second driving circuit for supply and blocking the electric power to the second heat generating element 112 is the same as that of the triac driving circuit 60, and therefore will be omitted from description. As described above, the first heat generating element 111 and the second heat generating element 112 are controlled independently of each other.
[Power Source Unit]
Next, with reference to (b) of
[Control of Electric Power Supply to Heater]
The CPU (controller) 32 sets a duty ratio (level) of the electric power depending on a detected temperature of the temperature detecting element 54 for every one control period, which is a plurality of periods of an AC waveform of the commercial power source 50. The driving circuits 60 and 70 are controlled by the CPU 32 so that the electric power supplied to each of the first and second heat generating elements 111 and 112 provides the duty ratio set by the CPU 32.
Specifically, the electric power control by the CPU 32 in the case where the electric power of the duty ratio P=75% is intended to be supplied to the heater 100 (in the case where a level of the total electric power supplied to the first and second heat generating elements 111 and 112 corresponds to the duty ratio of 75%) will be described using each of operational waveforms in 4 full-wave periods of the commercial power source voltage. The 4 full waves of the commercial power source voltage refer to a voltage that correspond to 4 periods of the commercial power source voltage, and is 8 half waves in terms of the half wave. In
When the commercial power source voltage 501 is inputted into the zero-cross generating circuit 57, the zero-cross generating circuit 57 generates a zero-cross signal 502 and outputs the zero-cross signal 502 to the CPU 32. In this embodiment, the 4 full waves constitute one control period. When the current having a phase control waveform (waveform such that the current flows from a halfway point of the half wave) is passed through one of the heat generating elements every half wave, electric power supply control such that the electric power supply of 100% (full energization (electric conduction)) is carried out for the other heat generating element or the electric power supply is not carried out (i.e., the electric power supply of 0% (non-energization) is carried out) for the other heat generating element is effected.
In
In the case where the electric power of 75% is supplied to the heater 100, the CPU 32 determines the supplied electric power (electric power duty ratio) every half wave so that the average supplied electric power for 4 full waves (half waves (i) to (viii)) is 75% for each of the first and second heat generating elements. That is, the CPU 32 sets the current waveform for each of the half waves. Hereinafter, a pattern such that the electric power supplied to the first heat generating element or the second heat generating element is set in each of the half waves in the one control period is referred to as a supplied electric power pattern. As shown in (c) of
The CPU 32 converts the phase of the ON-timing into a time, on the basis of the table (Table 1), by multiplying a half period of the waveform of the commercial power source voltage 501 detected by the zero-cross signal 502 by the ON-timing factor. For example, when the frequency of the commercial power source voltage 501 is 50 Hz and the ON-timing for supplying the electric power of 50% is converted into the time, the ON-timing is calculated as after a lapse of 5.0 ms (milliseconds) (=20 ms/2×0.5) from the timing when the zero-cross signal is detected. The CPU 32 outputs a high-level signal to the output port PA2 or PA3 after the lapse of 5.0 ms from the time when the level of the zero-cross signal 502 is changed from the high level to the low level or from the low level to the high level. As a result, the CPU 32 supplies the electric power of 50% to the first heat generating element 111 or the second heat generating element 112. In this way, by supplying the electric power every half wave depending on the supplied electric power pattern of each heater, it is possible to supply the electric power of 75% to the heater 100 in the 4 full waves.
[Power Source Current Supply Timing and Electric Power Supply Timing to Heater]
In
In
In
In
[Relationship Between Supplied Electric Power and Power Factor]
In
In the supplied electric power pattern shown in (a) of
On the other hand, in (a) of
Also in the supplied electric power pattern shown in (b) of
[Supplied Electric Power Pattern in this Embodiment]
Next, the supplied electric power pattern in this embodiment will be specifically described with reference to (b) and (c) of
For example, in the first full wave P (half wave (i)) in (b) of
In
As the supply ending timing of the power source current in this embodiment, the supply ending timing of the power source current prepared in advance is used. However, the supply ending timing of the power source current changes also depending on the power source voltage and the power source current, and therefore the supply ending timing may also be changed depending on the commercial power source voltage 501, the inlet current, a sequence of the image forming apparatus, and the like, and is not limited to that in this embodiment.
As described above, by using the supplied electric power pattern based on the supply ending timing of the power source current, it becomes possible to realize the high power factor even in the power source provided with no power factor improving circuit. The number of the heat generating elements for the heater 100, the length of the one control period and the setting method of the supplied electric power are not limited to those described in this embodiment.
[Power Control Process for Improving Power Factor]
In step S101, the CPU 32 calculates a duty ratio P (%) of the supplied electric power to the heater 100 (i.e., the duty ratio of the total electric power supplied to the first and second heat generating elements) on the basis of a set temperature of the heater 100, i.e., a target temperature in temperature control, and a present temperature detected by the temperature detecting element 54. The duty ratio P (%) calculated by the CPU in S101 is the average supplied electric power supplied to the entire heater 100 in the one control period, and, e.g., in the case of (c) of
In S103, the CPU 32 discriminates whether or not the duty ratio P is 50% or more. In the case where the CPU 32 discriminates that the duty ratio P is 50% or more in S103, the CPU 32 sets Piso(0) at 100% (Piso(0)=100) in S104. In the case where the CPU 32 discriminates that the duty ratio is not 50% or more in S103, the CPU 32 sets Piso(0) at 0% (Piso(0)=0) in S105. For example, in the case where the duty ratio P calculated by the CPU 32 in S101 is 85%, Piso(0)=100 is set. In S106, the CPU 32 sets Piso(1) at the power factor-improving duty ratio Pa calculated in S102 (Piso(1)=Pa), and sets Piso(2) at 100% (Piso(2)=100) in S107. For example, in the case where the power factor-improving duty ratio Pa calculated by the CPU 32 in S102 is 40%, Piso(1)=40 is set.
In S108, the CPU 32 discriminates whether or not a duty ratio of average supplied electric power in the 4 full waves set by using the duty ratio Pa (i.e., temperature duty ratio=((Piso(0)×2+Piso(1)+Piso(2))/4) is equal to the duty ratio P calculated in S101. As shown in (c) of
In S110, the CPU 32 discriminates whether or not Piso(1) is smaller than a value (Pa−X) obtained by subtracting a predetermined duty ratio X (%) from the power factor-improving duty ratio Pa. The threshold X is a value of 0-25, preferably a value of 0-15. In S110, in the case where the CPU 32 discriminates that Piso(1) is smaller than the value (Pa−X), the sequence goes to a process of S111. In S110, in the case where the CPU 32 discriminates that Piso(1) is not smaller than the value (Pa−X), the sequence goes to process of S112. In S106, Piso(1)=Pa is set, and therefore in the case where the sequence first goes to S110, the discrimination in S110 is “No”, so that the sequence goes to S112.
In S111, the power factor is rather lowered when the value is further subtracted from Piso(1), and therefore the CPU 32 does not subtract the value from Piso(1), but Piso(2) is decreased by 1% (Piso(2)=Piso(2)−1%). On the other hand, in S112, the CPU 22 decreases Piso(1) by 1% (Piso(1)=Piso(1)−1%). Further, in S113, the CPU 32 increases Piso(1) by 1% (Piso(1)=Piso(1)+1%). In the case where the CPU 32 makes the discrimination of “No” in S109, the value cannot be added to Piso(2)=100, and therefore the CPU 32 does not make the discrimination as in S110 but performs the process of S113. In the case where the CPU 32 discriminates that the temporary duty ratio is equal to the duty ratio P in S108, the process is ended. For example, in the case where the duty ratio P is 85% and the duty ratio Pa is 40%, the temporary duty ratio is 85% (=(100×2+40+100)/4), and is equal to the duty ratio P, and therefore the setting process of the supplied electric power pattern is ended.
In this embodiment, the control sequence, the tables and the circuit structure are not limited to those described above. By the electric power control in this embodiment, the supplied electric power pattern based on the supply ending timing of the power source current is set, so that it becomes possible to realize the high power factor even in the power source with no power factor-improving circuit. In this embodiment, the supplied electric power duty ratio P is calculated from the target temperature for effecting the temperature control and the present temperature detected by the temperature detecting element 54, and then the supplied electric power pattern is set. However, a constitution in which an optimum supplied electric power pattern is selected on the basis of the power source current supply ending timing from a plurality of tables of the supplied electric power patterns corresponding to combinations of predetermined duty ratios P with candidates for predetermined duty ratios Pa may also be employed. In this way, the setting method of the supplied electric power pattern is not limited to the method described in this embodiment.
In the above-described driving circuit for the heater 100, the triac is used. In the case where the triac is used, as described above, a constitution in which the supply ending timing of the power source current and the supply starting timing of the electric power by the phase control coincide with each other is employed. This embodiment is not limited to the driving circuit using the triac, but can also be applied to a driving circuit using, e.g., a field-effect transistor (FET).
In the case where the FET is used in the driving circuit for the heater 100, the power factor is improved when ON-timing or OFF-timing of the FET is controlled in the following manner. A description is provided with reference to (a) of
As described above, according to this embodiment, it is possible to improve the power factor while realizing downsizing of the image forming apparatus and a cost reduction.
In Embodiment 1, an example was described in which a supplied electric power pattern is set in which the power factor is improved on the basis of the power factor-improving duty ratio Pa calculated from the supply ending timing of the power source current and in which the electric power supply to the heater 100 is carried out in the supplied electric power pattern in one species of the control period. In general, a maximum current which can be supplied from the commercial power source 50 into the image forming apparatus is limited by standard, so that a high power factor is required only in the case where the current of the inlet 51 is in the neighborhood of the maximum current standard. Further, in order to minimize a temperature ripple as seen in the heater 100, the control period of the electric power supply is required to be shortened. Therefore, in Embodiment 2, an example will be described in which whether or not control for improving the power factor should be effected is discriminated depending on a detection result of the inlet current, and then the control period of the electric power supply and the supplied electric power pattern are switched. The structures of the image forming apparatus and the fixing device 30 are similar to those in Embodiment 1, and therefore the difference from Embodiment 1 will be principally described, and common constitutions will be omitted from description by adding the same reference numerals or symbols.
An inlet current detecting circuit in a heater driving circuit in this embodiment will be described with reference to (a) of
In
Specifically, in
The voltage outputted from the current transducer 180 is rectified by diodes 301 and 303 of the inlet current detecting circuit 181 shown in (b) of
The operational amplifier 312 controls a transistor 313 so that a current determined by a voltage difference between the reference voltage 317 inputted into (−) terminal thereof and the waveform inputted into (+) terminal thereof, and a resistor 311 is caused to flow into a capacitor 314. The capacitor 314 is charged with the current detected by the voltage difference between the reference voltage 317 inputted into (−) terminal and the waveform inputted into (+) terminal of the operational amplifier 312, and the resistor 311.
When a half-wave rectification section by the diode 303 is ended, there is no charging current to the capacitor 314, and therefore a resultant voltage value V2f is peak-held as shown in a waveform 706 in (g) of
Here, a transistor 315 is turned on in a half-wave rectification period, so that the charging current of the capacitor 314 is discharged. The transistor 315 is turned on and off by a DIS signal outputted from the CPU 32 shown in (h) of
That is, the peak-holding voltage V2f of the capacitor 314 is an integrated value of a squared value, in a half period, of the waveform which is voltage-converted, from the current waveform in the secondary side, by the current transducer 180. Then, the voltage of the capacitor 314 is outputted, as HCRRT1 signal shown in the waveform 706, in (g) of
In this embodiment, in the case where the inlet current I2 exceeds a predetermined current I4, the CPU 32 discriminates that there is a need to improve the power factor and sets the supplied electric power pattern based on the supply ending timing of the power source current I3 in the 4 full-wave periods described in Embodiment 1. The predetermined current I4 is a value determined in advance on the basis of the inlet current standard. On the other hand, in the case where the inlet current I2 is not more than the predetermined current I4, the CPU 32 discriminates that there is no need to improve the power factor, and gives high priority to shortening of the control period of the electric power supply, so that the CPU 32 sets the supplied electric power pattern in the 2 full-wave periods. In the case where the priority is given to the shortening of the control period, the one control period may only be required to be shorter than the supplied electric power pattern (e.g., 8 half waves) for improving the power factor and may only be required to include at least two half waves for effecting the phase control.
In this embodiment, switching detection of the supplied electric power pattern is made on the basis of the detection result of the inlet current detecting current 181. However, e.g., as in a constitution in which the supplied electric power pattern is switched depending on the commercial power source voltage or in a constitution in which the supplied electric power pattern is switched depending on an operation in a mode such as warm-up made or a print mode, the discrimination is not limited to that in this embodiment. Further, a constitution in which the switching between the supplied electric power pattern based on the supply ending timing of the power source current I3 in the 4 full-wave periods and the supplied electric power pattern based on the supply ending timing of the power source current I3 in the 8 full-wave periods is made depending on the control period or the like of required electric power control may also be employed. In this way, the type and the number of the supplied electric power patterns to be switched are not limited to those in this embodiment.
[Electric Power Control Process for Improving Power Factor]
The control process in this embodiment will be described along a flowchart of
On the other hand, in S202, in the case where the CPU 32 discriminates that the inlet current I2 is larger than the predetermined current I4, in S203, the CPU 32 sets the control period of the electric power supply at the 4 full-wave periods. Then, the CPU 32 carries out the processes from S102 and S113 as described above, so that the CPU 32 sets the supplied electric power pattern based on the supply ending timing of the power source current I3 in the 4 full waves. In this way, by performing the supplied electric power pattern setting process as shown in
As described above, according to this embodiment, the power force can be improved while realizing downsizing of the image forming apparatus and a cost reduction.
In Embodiments 1 and 2, the supply starting timing of the power source current I3 and the supply ending timing of the power source current I3 are prepared in advance. In Embodiment 3, a constitution applicable to even the case where the supply starting timing of the power source current I3 and the supply ending timing of the power source current I3 change depending on variations or the like in capacity of the commercial power source voltage 501 and the primary smoothing capacitor 86 will be described. That is, a method in which the supply starting timing of the power source current I3 and the supply ending timing of the power source current I3 can be detected without providing a dedicated detecting circuit even in the case where the supply starting timing of the power source current I3 and the supply ending timing of the power source current I3 change will be described. Also in this embodiment, a difference from Embodiments 1 and 2 will be principally described, and common constitutions will be omitted from description by adding the same reference numerals or symbols. In this embodiment, a method in which the supply starting timing of the power source current I3 and the supply ending timing of the power source current I3 are detected using the inlet current detecting circuit 181 and the heater driving circuit shown in (a) of
[Relationship Among Heater Current, Inlet Current and Supplied Electric Power to Heater]
In the above formula, P represents the supplied electric power, and R represents a resistance value of the heater 100.
On the other hand, the squared value of the inlet current I2 is different in slope for every region of the duty ratio when the duty ratio of the electric power supplied to the heater is increased. In the neighborhood of the duty ratio of 0% to 40% and the duty ratio of 75% to 100%, the slope is the same as the slope of the squared value of the heater current I1. However, in a range from 40% to 75% in duty ratio, it is understood that the slope (broken line) of the inlet current I2 is abrupt compared with other ranges. Further, the region where the duty ratio is 40% to 75% is an overlapping region with the power source current I3. That is, at a point (duty ratio of 40% in
Next, with reference to
(Case of (a) in
Calculation of the inlet current I2 in the case where the supply starting timing of the electric power supplied to the heater 100 is later than the supply ending timing of the power source current I3 will be described using the formulas 2 and 3. In
When the supply starting timing c of the electric power supplied to the heater is changed in a section from b to T, it is understood that the squared value of the inlet current I2 is changed correspondingly to a change in squared value of the heater current I1 in the second term of the formula 4. In (a) of
(Case of (b) in
Calculation of the inlet current I2 in the case where the supply starting timing of the electric power supplied to the heater 100 is later than the supply starting timing of the power source current I3 and earlier than the supply ending timing of the power source current I3 will be described with reference to (b) of
In the formula 5, a square of values of the section from a to c (the first term) is a square of only the instantaneous value i3(t) of the power source current I3. A section of c to b (the second term) is a resultant current section of the instantaneous value i3(t) of the power source current I3 and an instantaneous value i1(t) of the heater current I1. Further, in the formula 5, a section of b to T (the third term) is a section of only the instantaneous value i1(t) of the heater current I1. When the formula 5 is developed, the formula 5-1 is obtained. When the formula 5-1 is summarized, the squared value of the inlet current I2 can be expressed by the formula 5-2. In the formula 5-2, the first term represents the squared value of the power source current I3 in a section of a to b, and the second term represents the squared value of the heater current I1 in a section of c to T. In the formula 5-2, the third term represents the term generated by synthesizing the instantaneous value i3(t) of the power source current I3 and the instantaneous value i1(t) of the heater current I1 and then by squaring the resultant value. When the supply starting timing c of the electric power supplied to the heater is changed in a section from a to b, it is understood that the squared value of the inlet current I2 is changed correspondingly to a change the third term in addition to the change in the squared value of the heater current I1 in the second term of the formula 5-2. In (b) of
(Case of (c) in
Calculation of the inlet current I2 in the case where the supply starting timing of the electric power supplied to the heater 100 is earlier than the supply ending timing of the power source current I3 will be described with reference to (c) of
In the formula 6, a square of values of the section from c to a (the first term) is a square of only the instantaneous value i1(t) of the heater current I1. A section of a to be (the second term) is a resultant current section of the instantaneous value i3(t) of the power source current I3 and an instantaneous value i1(t) of the heater current I1. Further, in the formula 6, a section of b to T (the third term) is a section of only the instantaneous value i1(t) of the heater current I1. When the formula 6 is developed, the formula 6-1 is obtained. When the formula 6-1 is summarized, the squared value of the inlet current I2 can be expressed by the formula 6-2. In the formula 6-2, the first term represents the squared value of the heater current I1 in a section of c to T, and the second term represents the squared value of the power source current I3 in a section of a to b. In the formula 6-2, the third term represents the term generated by synthesizing the instantaneous value i3(t) of the power source current I3 and the instantaneous value i1(t) of the heater current I1 and then by squaring the resultant value. When the supply starting timing c of the electric power supplied to the heater is changed in a section from 0 to a, it is understood that the squared value of the inlet current I2 is changed correspondingly to a change in the squared value of the heater current I1 in the first term of the formula 6-2. In (c) of
Based on a principle described above, the slope of the squared value of the inlet current I2 is abrupt only in a region where the heater current overlaps with the power source current I3, and by using this principle, it is possible to detect the supply starting timing of the power source current I3 and the supply ending timing of the power source current I3. In this embodiment, the supply starting timing of the power source current I3 and the supply ending timing of the power source current I3 are calculated from the slope of the squared value of the inlet current I2. However, as the method of detecting the supply starting timing of the power source current I3 and the supply ending timing of the power source current I3, in order to simplify the calculation or the like, a method is provided in which the timing is calculated from a waveform obtained by subtracting the squared value of the heater current I1 from the squared value of the inlet current I2. Further, as the method of detecting the supply starting timing of the power source current I3 and the supply ending timing of the power source current I3, there is also a method in which the timing is calculated from a slope of a value obtained by subtracting the heater current I1 from the inlet current value I2. Thus, these methods are not limited to those in this embodiment.
[Detecting Process of Supply Starting Timing and Supply Ending Timing of Power Source Current]
A detecting process of the supply starting timing and the supply ending timing of the power source current I3 passing through the power source unit 53 by using the inlet current detecting circuit 181 in this embodiment will be described in the flowchart of
In S305, the CPU 32 supplies the electric power of Pn % to the heater 100.
In S306, the CPU 32 discriminates whether or not the rising edge of the zero-cross signal 502 outputted from the zero-cross generating circuit 57, and in the case where the CPU 32 discriminates that the rising edge of the zero-cross signal 502 is not detected, the CPU 32 repeats the process of S306. In S306, in the case where the CPU 32 discriminates that the rising edge of the zero-cross signal 502 is detected, the sequence goes to a process in S307. In S307, the CPU 32 detects the inlet current, when the electric power of Pn % is supplied in S305, by the inlet current detecting circuit 181, and then obtains a squared value of the inlet current. Hereinafter, the inlet current when the electric power of Pn % is supplied will be described as I2n. The square value thereof is I2n2.
In S308, the CPU 32 discriminates whether or not the counter n is 2 or more, and in the case where the CPU 32 discriminates that the counter n is not 2 or more, the sequence returns to the process of S303. In S308, in the case where the CPU 32 discriminates that the counter n is 2 or more, the sequence goes to a process of S309. In S309, the CPU 32 applies a change amount An of the slope of the squared value of the inlet current I2n to the supplied electric power Pn %.
The calculated value of An is stored in, e.g., RAM 32b.
In S310, the CPU 32 discriminates whether or not the supplied electric power Pn % is 90 or more, and in the case where the CPU 32 discriminates that the supplied electric power Pn % is not 90 or more, the sequence returns to the process of S303. That is, the CPU 32 calculates the inlet current I2n at the supplied electric power Pn % and the change amount An of the slope of the squared value of the inlet current I2n to each of values of the supplied electric power Pn % in the processes S303 to S309 until the supplied electric power Pn % reaches 90 or more. In S310, in the case where the CPU 32 discriminates that the supplied electric power Pn % is 90 or more, the sequence goes to a process of S311.
In S311, the CPU 32 reads out the value of An stored in the RAM 32b, and obtains a duty ratio PA max when the change amount An of the slope of the squared value of the inlet current I2n to the supplied electric power Pn % is a maximum, and a duty ratio PA mm when the change amount An is a minimum. The duty ratios PAmax and PAmin are not limited to those obtained in this embodiment, but may also be those obtained by other known extracting methods of maximum and minimum values. As described with reference to
In the case where the detecting process in this embodiment is applied to Embodiments 1 and 2, e.g., detecting process in this embodiment is carried out during the process of S102 in
As described above, by the detecting process in this embodiment, it is possible to detect the supply starting timing of the power source current I3 and the supply ending timing of the power source current I3. In this embodiment, the duty ratio is gradually changed from 10% to 90% in an increment of 1% (S304 and S310 in
As described above, according to this embodiment, it is possible to improve the power factor while realizing the downsizing of the image forming apparatus and a cost reduction.
In Embodiment 3, the example in which the duty ratio of the electric power supplied to the heater is changed from 10% to 90% in the increment of 1% to calculate the supply starting timing of the power source current I3 and the supply ending timing of the power source current I3 was described. In Embodiment 4, a constitution is employed in which whether or not the supply starting timing of the power source current I3 and the supply ending timing of the power source current I3 fluctuate depending on a variation in load or the commercial power source voltage 501 is checked. Further, an example in which the supply starting timing and the supply ending timing of the power source current I3 are detected again and then whether or not there is a need to make the change is discriminated will be described. Constitutions similar to those described in Embodiments 1 to 3 will be omitted from description by adding the same reference numerals or symbols.
In S401, the CPU 32 makes the initial setting of respective variables. That is, the CPU 32 sets supplied electric power Pk at PAmin−1 (Pk=PAmin−1), and sets a counter k at 0 (k=0). That is, as the supplied electric power Pk, a value which is smaller than the supply starting timing PAmin of the power source current I3 by 1% is set. The process of S303 is the same as that described in Embodiment 3, and therefore will be omitted from description. In S402, the CPU 32 supplies the electric power Pk %. The process of S306 is the same as that described in Embodiment 3, and therefore will be omitted from description.
In S403, the CPU 32 detects the inlet current, when the electric power of Pk % is supplied in S402, by the inlet current I2k detecting circuit 181, and then obtains a squared value of the inlet current I2k. In S404, the CPU 32 increments the supplied electric power Pk % and the counter k by 1 (Pk=Pk+1, k=k+1). In S405, the CPU 32 discriminates whether or not the counter k is 2 or more, and in the case where the CPU 32 discriminates that the counter k is not 2 or more, the sequence returns to the process of S303.
In S405, in the case where the CPU 32 discriminates that the counter n is 2 or more, in S406, the CPU 32 applies a change amount Ak of the slope of the squared value of the inlet current I2k to the supplied electric power Pk %.
In S407, the CPU 32 discriminates whether or not an absolute value |Ak| of the slope change amount Ak is larger than a predetermined slope change amount Ax. The predetermined slope change amount Ax is a threshold for discriminating whether or not the slope change amount Ak changes. In S407, in the case where the CPU 32 discriminates that the absolute value |Ak| of the slope change amount Ak is larger than the predetermined slope change amount Ax, the CPU 32 discriminates that the slope change amount Ak of the squared value of the inlet current I2k, and then the sequence goes to a process of S408. In S401, the CPU 32 sets, as the supplied electric power Pk %, a value which is 1% smaller than the supplied electric power PAmin corresponding to that at the supply starting timing of the power source current I3. For this reason, in S406, the CPU 32 calculates the slope change amount in the neighborhood of the supplied electric power PAmin %, and when the slope of the squared value of the inlet current I2k changes, |Ak| is larger than the predetermined slope change amount Ax. In S408, the CPU 32 discriminates that there is no need to make the change since the supply starting timing of the power source current I3 is not fluctuating.
On the other hand, in S407, in the case where the CPU 32 discriminates that the absolute value |Ak| of the slope change amount Ak is not larger than the predetermined slope change amount Ax, i.e., in the case where the slope of the squared value of the inlet current I1k does not change, the sequence goes to a process of S409. In S409, the CPU 32 detects that the change is needed since the supply starting timing of the power source current I3 fluctuates. In S409, in the case where the CPU 32 discriminates that the change in supply starting timing of the power source current I3 is needed, the CPU 32 carries out the detecting process of the supply starting timing of the power source current I3 described in Embodiment 3.
[Discriminating Process Whether or not Change is Needed (End Timing)]
A discriminating process as to whether or not the supply ending timing of the power source current I3 should be changed in this embodiment will be described with reference to
In S407, in the case where the CPU 32 discriminates that the absolute value |Ak| of the slope change amount Ak, calculated in S406, of the squared value of the inlet current I2 is larger than the predetermined slope change amount Ax, the sequence goes to a process of S412. In S412, the CPU 32 discriminates that there is no need to make the change since the supply ending timing of the power source current I3 is not fluctuating. On the other hand, in S407, in the case where the CPU 32 discriminates that the absolute value |Ak| of the slope change amount Ak of the squared value of the inlet current I2k is the predetermined slope change amount Ax or less, the sequence goes to a process of S413. In S413, the CPU 32 detects that the change is needed since the supply ending timing of the power source current I3 fluctuates. In S413, in the case where the CPU 32 discriminates that the change in the supply ending timing of the power source current I3 is needed, the CPU 32 carries out the detecting process of the supply ending timing of the power source current I3 described in Embodiment 3.
In this way, the CPU 32 carries out the detecting process in Embodiment 4 only in the case where the CPU 32 discriminates that the supply starting timing or the supply ending timing of the power source current I3 fluctuates. Then, the CPU 32 updates information of the supply starting timing or the supply ending timing of the power source current I3 stored in the RAM 32b. Then CPU 32 carries out the electric power control process for improving the power factors in Embodiments 1 and 2 by using PAmax or PAmin which is not updated (not fluctuated) or is updated (is fluctuated).
As described above with reference to
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 purpose of the improvements or the scope of the following claims.
This application claims priority from Japanese Patent Application No. 207243/2013 filed Oct. 2, 2013, which is hereby incorporated by reference.
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