JP6922622B2 - Image forming device - Google Patents

Description

The present invention relates to an image forming apparatus that prints an image on a sheet.

Conventionally, as an image forming apparatus for printing an image on a sheet which is an object to be printed, an image forming apparatus for fixing and printing an image with toner once formed on the sheet by heating has been known. Further, the heating of the above image is generally performed by the fixing portion heated by the energized heater, but in order to keep the fixing portion as constant as possible with respect to the target temperature, the energized state of the heater It is important to control properly.

For example, Japanese Patent Application Laid-Open No. 2011-164387 describes the wave number control for controlling the waveform of the current supplied to the heater on or off in half-wave units, and the wave number control for controlling on or off at an arbitrary phase angle within the half-wave. It has been proposed to suppress flicker and harmonic currents by combining phase control.

Japanese Unexamined Patent Publication No. 2011-164387 (pages 8-11)

Here, in Patent Document 1, a plurality of patterns having different duty ratios are prepared with reference to the duty ratio for the waveform pattern of the current that combines wave number control and phase control, and the waveform pattern is switched for each control cycle. The heater is controlled to energize. However, even if control for switching the energized state of the heater between waveform patterns having different duty ratios is performed as in Patent Document 1, flicker and harmonic current cannot be sufficiently suppressed. Further, in the above-mentioned energization control of the heater, it is required to reduce the temperature ripple in addition to the flicker and the harmonic current.

In order to reduce temperature ripple in addition to flicker and harmonic current, not only the duty ratio of the waveform pattern of the current supplied to the heater is changed, but also the shape of the waveform pattern and the switching mode of the waveform pattern are more optimal. Need to be.

The present invention has been made to solve the above-mentioned conventional problems, and when controlling the energization of a heater, a plurality of different control patterns corresponding to different temperatures are stored in advance by dividing them into a plurality of groups. , When switching the control pattern of the current supplied to the heater, the control pattern can be switched in different modes according to the change direction of the detected temperature of the fixing part, and the temperature ripple can be reduced by switching in consideration of the above group. At the same time, it is an object of the present invention to provide an image forming apparatus capable of suppressing harmonic current and flicker.

In order to achieve the above object, the image forming apparatus according to the present application includes a heater that is heated by electric power supplied from an AC power source, a fixing portion that includes the heater and fixes an image by toner formed on a sheet, and an AC power source. A switching element provided between the heater and the switching element that switches between an on state in which the AC power supply and the heater are conductive and an off state in which the AC power supply and the heater are not conducted. A temperature sensor that outputs a signal corresponding to the temperature of the fixing unit and a plurality of continuous half waves of the waveform of the AC power supply are used as control cycles, and the switching element is turned on in the control cycle at different temperatures. The detection temperature, which is the temperature of the fixing unit detected based on the signal input from the temperature sensor, is set to the memory that stores the table corresponding to the on information, which is the information indicating the period to be performed, and the table. The on information includes a control device that sets the corresponding on information and controls the switching element so that the switching element is in the on state for a period indicated by the set on information. Of the plurality of half waves constituting the control cycle, the first information indicating one or a plurality of half waves in which the switching element is turned on for the first period, and each of the first information shown in the first information with respect to the control cycle. The second information indicating the first ratio, which is the total ratio of the first period in the half wave, and one or more of the plurality of half waves constituting the control cycle other than the half wave indicated by the first information. In each of the half waves, the third information indicating the second period, which is the second period in which the switching element is turned on and is shorter than the first period, and the third information with respect to the control cycle. The table includes the fourth information indicating the second ratio, which is the total ratio of the second period in each of the indicated half waves, and the table shows that the first ratios indicated by the second information are the first values of each other. In addition, the first group including the plurality of on-informations in which the second ratio indicated by the fourth information is different from each other and the first ratio indicated by the second information are larger than the first value. The control device is included in the first group, which is divided into a second group including a plurality of the on-information, which is a second value and the second ratio indicated by the fourth information is different from each other. When the detection temperature drops while the on information is set so that the second ratio of the on information becomes the maximum value, the second ratio of the on information included in the second group Is the maximum value It is characterized in that the on information is set.

When switching the control pattern of the current supplied to the heater, the image forming apparatus of the present application switches the control pattern in a different manner according to the changing direction of the detection temperature of the fixing portion, and also considers the group for dividing the control pattern. By performing this, it is possible to reduce the temperature ripple and also to suppress the harmonic current and flicker.

It is a schematic diagram which shows schematic structure of the printer which is this embodiment. It is a block diagram which shows the electrical structure of the printer. It is a block diagram which shows the electrical structure necessary for performing the temperature control of a fixing part. It is a figure which shows the temperature table used for the temperature control of a fixing part. It is a figure which showed an example of the waveform pattern of the current supplied to a heater at the time of control by the on information included in a temperature table. It is a flowchart of the temperature control processing program of the fixing part which concerns on this embodiment. It is a figure which showed an example of the switching mode of on information. It is a figure which showed an example of the switching mode of on information. It is a figure which showed the modification.

Hereinafter, an embodiment in which the image forming apparatus according to the present application is embodied in a printer will be described with reference to the drawings. FIG. 1 shows a schematic configuration of the printer 10 of the present embodiment. In the following description, the front-back direction and the up-down direction are as described on the paper.

[Overall configuration of printer]
The printer 10 according to the present embodiment is an electrophotographic color laser printer, and prints a desired image on the sheet P. However, the printer 10 may be a monochrome laser printer. The printer 10 includes a main body housing 11, an operation panel 13, three paper feed trays 15A, 15B, 15C, a printing unit 17, a fixing unit 19, and the like.

The main body housing 11 has a substantially box shape, and houses a printing unit 17, paper feed trays 15A to 15C, and the like inside. The operation panel 13 is, for example, a touch panel and is provided on the upper surface of the main body housing 11. The operation panel 13 displays the operating status of the printer 10 and accepts input operations by the user. The input operation by the user here includes, for example, an operation of instructing the printing unit 17 to stop printing, an operation of inputting sheet information related to the sheet P replenished in the paper feed trays 15A to 15C, and the like.

The sheet information includes, for example, a sheet type indicating the thickness of the sheet P. Sheet types include, for example, thick paper, plain paper, and thin paper.

Each of the paper feed trays 15A to 15C is provided at the lower part in the main body housing 11, and accommodates a plurality of sheets P to be used for printing an image. For example, each of the paper feed trays 15A to 15C stores sheets P having different thicknesses. In the following description, when each of the paper feed trays 15A to 15C is generically described without distinction, it is referred to as the paper feed tray 15.

The paper feed tray 15 is configured so that it can be pulled out to the front side with respect to the main body housing 11. Further, the paper feed tray 15 is configured so that it can be removed and attached to the main body housing 11 after being pulled out to the front side. The user can pull out the paper feed tray 15 from the main body housing 11 and replenish the sheet P on the paper feed trays 15A to 15C.

The main body housing 11 is provided with tray sensors 21A, 21B, 21C corresponding to each of the paper feed trays 15A to 15C and detecting whether or not the paper feed trays 15A to 15C are attached. The tray sensors 21A to 21C are provided in front of and above the paper feed trays 15A to 15C. Each of the tray sensors 21A to 21C is, for example, an optical sensor, emits light toward each of the paper feed trays 15A to 15C, and outputs a signal according to the intensity of the reflected light to the control device 51 (see FIG. 2). .. The tray sensors 21A to 21C output signals having different intensities to the control device 51 depending on whether the paper feed trays 15A to 15C are in the mounted state or not.

Further, the main body housing 11 is provided with paper feed rollers 23A, 23B, 23C for feeding the sheets P stored in each of the paper feed trays 15A to 15C. The sheets P on the paper feed trays 15A to 15C are separated one by one by each of the paper feed rollers 23A to 23C and conveyed to the transfer path 31. The sheet P transported to the transport path 31 is transported to the printing unit 17. That is, it can be said that the sheet P housed in the paper feed tray 15 in the mounted state is in a position where the sheet P can be supplied to the printing unit 17 by the paper feed rollers 23A to 23C.

The printing unit 17 is provided above the paper feed tray 15 in the main body housing 11, and prints a desired image on the sheet P. The printing unit 17 includes a scanner unit 33, four image forming units 35, a belt unit 37, and the like. The scanner unit 33 is provided in the upper part of the main body housing 11, and includes a polygon motor, a polygon mirror, a laser light source, a reflection mirror, a lens, and the like (not shown). The scanner unit 33 emits a laser beam derived from a desired image from a laser light source, and performs an electrostatic latent image on the surface of a photoconductor drum 38 of each image forming unit 35 via a polygon mirror, a reflection mirror, a lens, and the like. To generate.

The four image forming units 35 are provided between the scanner unit 33 and the belt unit 37 in the vertical direction, and are arranged side by side in the front-rear direction. Each image forming unit 35 corresponds to the toner colors of yellow, magenta, cyan, and black in order from the front, for example. The image forming unit 35 uniformly charges the surface of the photoconductor drum 38 with a positive electrode by a charger (not shown). The image forming unit 35 supplies a developer (toner) to the electrostatic latent image generated on the surface of the photoconductor drum 38, and develops the electrostatic latent image to generate a toner image.

The belt unit 37 is provided below the four image forming units 35 and above the paper feed tray 15. The belt unit 37 conveys the sheet P to the fixing portion 19 by rotating the annular belt. Further, a transfer roller 39 is provided inside the belt unit 37. The transfer roller 39 transfers the toner image on the surface of the photoconductor drum 38 to the sheet P by applying a negative transfer bias.

The fixing portion 19 is provided behind the belt unit 37 and heat-fixes the toner image transferred to the sheet P. The fixing portion 19 includes a heating roller 41 and a nip roller 43. The heating roller 41 includes a heater 49 such as a halogen lamp, and is provided so as to be rotatable and driveable. The heater 49 is a heating device that heats the heating roller 41 with electric power supplied from the AC power supply, and the AC power supply and the heater 49 are provided by a switching element provided between the AC power supply and the heater 49 as described later. The on state, which is a state in which the AC power supply is conducting, and the off state, which is a state in which the AC power supply and the heater 49 are not conducted, are switched. The nip roller 43 is arranged below the heating roller 41 and is in contact with the heating roller 41 so as to press it. The fixing portion 19 passes the sheet P by holding the sheet P carrying the toner image by the heating roller 41 and the nip roller 43 while heating the sheet P.

Inside the fixing portion 19, a temperature sensor 47 for detecting the temperature of the fixing portion 19 is provided. The temperature sensor 47 is provided along the axial direction of the heating roller 41 at a position close enough not to come into contact with the heating roller 41. The temperature sensor 47 is a thermistor or the like, and outputs a signal corresponding to the outer peripheral temperature of the heating roller 41.

A paper ejection tray 45 is provided downstream of the fixing portion 19 and above the main body housing 11. As shown in FIG. 1, the transport path 31 includes a substantially S-shaped path from the paper feed position of the paper feed tray 15 to the paper output tray 45 via the printing unit 17.

[Electrical configuration of printer]
FIG. 2 shows the electrical configuration of the printer 10. The printer 10 includes a control device 51, a timer 53, a memory 55, and the like. The control device 51 includes a CPU and a RAM, and controls each part of the printer 10 in an integrated manner by executing a process based on a control program stored in the memory 55. The respective parts referred to here are the above-mentioned operation panel 13, the printing part 17, the fixing part 19 (including the heater 49), and the like. For example, the control device 51 maintains the temperature of the fixing portion 19 (more specifically, the heating roller 41 constituting the fixing portion 19) at the target temperature while the sheet P passes through the fixing portion 19. To control. As a result, the temperature of the heating roller 41 is kept within the permissible temperature range including the target temperature. The target temperature is, for example, 200 ° C. In the following description, the temperature of the heating roller 41 is also referred to as the temperature of the fixing portion 19. Further, the control device 51 is not limited to software processing for executing a control program by the CPU, and may be configured to include dedicated hardware such as an ASIC and control each part of the printer 10 by executing the hardware processing.

The timer 53 starts or stops the time measurement in response to the input of the signal of the control device 51. When the timer 53 starts measuring the time, the timer 53 counts up the timer count value every time a certain time elapses. The timer 53 may be hardware built in the control device 51, or may be configured by software processing for executing a control program by the CPU.

The memory 55 stores various control programs for controlling the printer 10, a temperature table described later, various setting data, and the like. Sheet information and print data are stored in the memory 55. The sheet information in the memory 55 is stored in association with the paper feed tray 15 and the print job. Information such as the sheet type of the sheet P is set in this sheet information. The print data in the memory 55 is stored in association with the print job. When printing, the control device 51 supplies the sheet P from the paper feed tray set for the print job among the paper feed trays 15A to 15C, and prints an image based on the print data of the print job by the printing unit 17. do. The "tray 1 to 3" in FIG. 2 correspond to each of the paper feed trays 15A to 15C.

The operation panel 13 outputs a signal corresponding to an input operation to the touch panel by the user to the control device 51. Further, the operation panel 13 displays an image in response to a command from the control device 51.

The tray sensors 21A to 21C output a signal corresponding to the insertion / removal operation of the paper feed tray 15 to the control device 51. As a result, the control device 51 can detect the mounting state or the removing state of the paper feed tray 15. The state in which the paper feed tray 15 is mounted means a state in which the entire paper feed tray 15 is housed in the main body housing 11. The removed state of the paper feed tray 15 means, for example, a state in which a part or all of the paper feed tray 15 is pulled out from the main body housing 11. In other words, the removed state of the paper feed tray 15 means a state in which the paper feed tray 15 is not in the mounted state. The tray sensors 21A to 21C may not be optical sensors, but may be, for example, switch-type sensors pressed by the paper feed tray 15 in the mounted state. Further, in order to determine whether or not the sheet P is located at a position where the sheet P can be supplied to the printing unit 17 by the paper feed rollers 23A to 23C, the paper feed tray 15 is moved by using the tray sensors 21A to 21C. Instead of detecting whether or not it is in the mounted state, for example, the presence or absence of the sheet P in the paper feed tray 15 provided at a position facing the paper feed tray 15 in the mounted state in the main body housing 11. The presence or absence of the sheet P in the paper feed tray 15 may be detected by using a sensor that outputs the corresponding signal to the control device 51.

The temperature sensor 47 outputs a signal corresponding to the outer peripheral temperature of the heating roller 41 to the control device 51. As a result, the control device 51 can acquire the outer peripheral temperature of the heating roller 41 as the detection temperature of the fixing unit 19.

The zero-cross detection circuit 57 and the switching element 59 are used when the control device 51 controls the temperature of the fixing unit 19. The details will be described later.

In the following, the electrical configuration necessary for controlling the temperature of the fixing portion 19 will be described with reference to FIG.

The zero-cross detection circuit 57 detects the zero-cross timing of the drive voltage applied from the power supply 61, which is an AC power supply, and outputs the detection signal to the control device 51. The zero cross timing is a point at which the voltage becomes 0 (zero) in the drive voltage waveform. The current value also becomes 0 at this zero cross timing. The switching element 59 is provided between the power supply 61 and the heater 49, and under the control of the control device 51, the switching element 59 conducts the power supply 61 and the heater 49 in an on state in which the power supply 61 and the heater 49 are electrically connected to each other. Switch between the off state and the off state.

Then, the control device 51 controls the energization of the heater 49 by performing phase control and wave number control based on the detection signal of the zero cross detection circuit 57 by the switching element 59. At that time, the control device 51 switches between the on state and the off state by using the temperature difference between the detection temperature of the fixing unit 19 acquired by the temperature sensor 47 and the target temperature and the temperature table stored in the memory 55. ..

More specifically, the temperature table is information indicating the period during which the switching element 59 is turned on in the control cycle for each different temperature, with a plurality of continuous half waves of the waveform of the AC power supply as the control cycle. It is a table corresponding to. Then, the control device 51 sets the on information corresponding to the detected temperature of the fixing unit 19 acquired by the temperature sensor 47 with reference to the temperature table, and the switching element 59 is turned on for the period indicated by the set on information. The switching element 59 is controlled so as to be in a state. As a result, the temperature of the fixing unit 19 is controlled. The details of the temperature table will be described later.

Further, in the present embodiment, as the temperature control of the fixing unit 19, wave number control for controlling on or off in half-wave units and phase control (or anti-phase control) for controlling on or off at an arbitrary phase angle within the half-wave are performed. ) Is combined to perform control. For example, in wave number control, the switching element 59 is controlled so that the switching element 59 continues to be in the ON state from the time when the switching element 59 is turned on by the zero cross timing when the half wave starts until the zero cross timing when the half wave ends. Since phase control and wave number control are known techniques, detailed description thereof will be omitted. Further, in the following description, the energization ratio of the heater 49 is referred to as a duty ratio.

[Temperature table]
Next, the temperature table stored in the memory 55 is shown with reference to FIG. FIG. 4 shows an example of a temperature table used for temperature control of the fixing unit 19.
As shown in FIG. 4, information indicating a period during which the switching element 59 is turned on in the control cycle (hereinafter referred to as on information) is provided for each different temperature with a plurality of continuous half waves of the waveform of the AC power supply as the control cycle. It is a corresponding table. It should be noted that the temperature particularly corresponds to the temperature difference with respect to the target temperature, and in particular, in FIG. 4, the difference (° C.) of the temperature below the target temperature is associated as the "difference from the target temperature". For example, if the "difference from the target temperature" is 1.0, it indicates that the temperature is 1 ° C. lower than the target temperature. Further, "on information" corresponds to each information of "Total", "wavenumber", "wavenumber pattern", "phase", and "phase duty ratio in half wave" in the temperature table shown in FIG. ..

In addition, each information included in the "on information" will be described.
"Wavenumber pattern": Information indicating one or more halfwaves (halfwaves for wavenumber control) in which the switching element 59 is turned on for the first period among the plurality of halfwaves constituting the control cycle. , Corresponds to the "first information" of the present invention. For example, [100] indicates a waveform pattern consisting of three half waves controlled in the order of on, off, and off in half wave units.
"Wave number": Information indicating the first ratio, which is the total ratio of the first period in each half wave represented by the "wave number pattern", to the control period, and corresponds to the "second information" of the present invention. ..
"Phase duty ratio in half wave": One or more half waves (half wave for phase control) other than the half wave indicated by "wave number pattern" among the multiple half waves constituting the control period, respectively. In the second period in which the switching element 59 is turned on, which is information indicating a second period shorter than the first period, and corresponds to the "third information" of the present invention.
"Phase": Information indicating the second ratio, which is the total ratio of the second period in each half wave indicated by the "phase duty ratio in half wave" to the control period, and is the "fourth" of the present invention. Corresponds to "information".
"Total" ... A value obtained by summing the first ratio of the above "wave number" and the second ratio of the "phase".

Here, FIG. 5 is a diagram showing an example of a waveform pattern of the current supplied to the heater 49 when controlled by the on information included in the temperature table. In the example shown in FIG. 5, control is performed with on information of "Total" 43%, "Wave number" 33%, "Wave number pattern" [100], "Phase" 10%, and "Phase duty ratio in half wave" 15%. The waveform pattern of the current in the case is shown. In the present embodiment, the "wavenumber pattern" is set to [100] when, for example, the "wavenumber" is 33%, but it is turned off when the half wave is turned on, as in [010] and [001]. The order of the half waves may be changed as appropriate.

As shown in FIG. 5, the waveform pattern of the current when controlled based on the on information is a waveform pattern in which a half wave for wave number control and a half wave for phase control are combined. The half wave for wave number control is a half wave that is turned on or off in half wave units, and the period in which it is turned on is the first period described above. On the other hand, the half wave for phase control is a half wave that is controlled to be turned on at an arbitrary phase angle within the half wave, and the period in which the half wave is turned on is the second period described above. In the present embodiment, the phase control that controls on at an arbitrary phase angle in the half wave is used, but the antiphase control that controls off at an arbitrary phase angle in the half wave may be used.

The temperature table shown in FIG. 5 is an example, and the numerical values of the first ratio of "wave number" and the second ratio of "phase" can be changed as appropriate, but the maximum value of the second ratio is 10% or less. It is desirable to do. Further, it is desirable that the ratio of the first period to the half cycle of the AC power supply is 90% or more.

Further, as shown in FIG. 4, the temperature table classifies on-information in which the first ratio indicated by "wave number" is the same and the second ratio indicated by "phase" is different from each other in a group unit. For example, in the example shown in FIG. 4, the group is divided into 10 groups 1 to 10, but the number of groups can be changed as appropriate. In the following description, they are referred to as group 1, group 2, ... (Omitted below) in ascending order of the first ratio indicated by "wave number".

[Temperature control process of fixing part]
Subsequently, the temperature control process of the fixing unit 19 executed by the control device 51 of the printer 10 having the above configuration will be described with reference to FIG. FIG. 6 is a flowchart of the temperature control processing program of the fixing unit 19 according to the present embodiment. Here, the temperature control processing program is executed after the printing operation of the printer 10 is started, and the energized state of the heater 49 is determined based on the temperature difference from the target temperature of the fixing unit 19 and the temperature table (FIG. 4). This is a program for causing the fixing unit 19 to reach the target temperature by sequentially switching to the optimum pattern and keeping the fixing unit 19 constant with respect to the target temperature after reaching the target temperature. The program shown in the flowchart in FIG. 6 below is stored in the memory 55 included in the printer 10 and executed by the control device 51.

First, in step 1 (hereinafter abbreviated as S) 1, the control device 51 sets the ON information of the pattern A among the ON information defined in the temperature table (FIG. 4). The on-information of the pattern A is the on-information having the highest second ratio of "phase" in each group.

Immediately after the start of the printing operation, in order to bring the temperature of the fixing unit 19 to the target temperature as soon as possible, it is desirable to preferentially set the on information having a high ratio of "Total". For example, at first, the on information of the pattern A of the group 1 having the highest ratio of "Total" is set, and as the temperature of the fixing portion 19 detected by the temperature sensor 47 rises, the ratio of "Total" gradually increases. Switch to the lower pattern A on information. When the difference from the target temperature becomes −33 ° C. or less, it is desirable to select the on information to be set in correspondence with the difference temperature in the temperature table of FIG. For example, when the difference temperature becomes -24 ° C, the on information of the pattern A of the group 4 is set, and when the difference temperature becomes -20.5 ° C after that, the pattern A of the group 5 is set. On Set information.

Subsequently, in S2, the control device 51 reaches the target temperature of the fixing unit 19 based on the temperature of the fixing unit 19 detected by the temperature sensor 47, and the temperature ripple is equal to or less than the specified value (the temperature change is settled to some extent). It is judged whether or not it becomes).

Then, when it is determined that the temperature of the fixing portion 19 reaches the target temperature and the temperature ripple is equal to or less than the specified value (S2: YES), the process proceeds to S3. On the other hand, when it is determined that the temperature of the fixing portion 19 has not reached the target temperature, or even if the temperature ripple has reached the target temperature, the temperature ripple is not equal to or less than the specified value (S2: YES), the process returns to S1.

In S3, the control device 51 continuously sets the ON information of the pattern A among the ON information defined in the temperature table (FIG. 4). The ON information of the pattern A that is continuously set in S3 is the ON information that is finally set in S1 or S8, S13, and S16 that were executed most recently.

Next, in S4, the control device 51 determines whether or not the temperature of the fixing unit 19 detected by the temperature sensor 47 has risen.

Then, when it is determined that the temperature of the fixing portion 19 has risen (S4: YES), the process proceeds to S5. On the other hand, when it is determined that the temperature of the fixing portion 19 has dropped (S4: NO), the process proceeds to S15.

In S5, the control device 51 switches to the on information of the pattern B having a smaller phase in the same group to which the currently set on information belongs. It should be noted that the on information of the pattern B whose phase is only one step smaller than the current on information may be switched, or the on information of the pattern B corresponding to the current temperature difference (that is, the phase is 2 than the current on information). You may switch to on-information that is smaller than the stage.

Next, in S6, the control device 51 determines whether or not the temperature of the fixing unit 19 detected by the temperature sensor 47 has risen.

Then, when it is determined that the temperature of the fixing portion 19 has risen (S6: YES), the process proceeds to S7. On the other hand, when it is determined that the temperature of the fixing portion 19 has dropped (S6: NO), the process proceeds to S12.

In S7, the control device 51 determines whether or not the currently set ON information of the pattern B has the smallest phase (the second ratio is the smallest) in the group to which the ON information belongs.

Then, when it is determined that the currently set ON information of the pattern B has the smallest phase in the group to which the ON information belongs (S7: YES), the process proceeds to S8. On the other hand, when it is determined that the currently set ON information of the pattern B is not the minimum phase in the group to which the ON information belongs (S7: NO), the process proceeds to S9.

In S8, the control device 51 switches to the on information of the pattern A of the group in which the wave number is one step smaller than the group to which the on information currently set belongs. For example, when the on information of the pattern A of the group 6 shown in FIG. 4 is set, it is switched to the on information of the pattern A of the group 7. After that, it shifts to S10.

On the other hand, in S9, the control device 51 switches to the on information of the pattern B having a smaller phase in the same group to which the currently set on information belongs. It should be noted that the on information of the pattern B whose phase is only one step smaller than the current on information may be switched, or the on information of the pattern B corresponding to the current temperature difference (that is, the phase is 2 than the current on information). You may switch to on-information that is smaller than the stage.

After that, in S10, the control device 51 determines whether or not to continue the temperature control of the fixing unit 19, that is, whether or not to continue the printing operation.

Then, when it is determined that the temperature control of the fixing unit 19 is continued (S10: YES), that is, when it is determined that the printing operation is continued, the process proceeds to S11. On the other hand, when it is determined that the temperature control of the fixing unit 19 is not continued (S10: NO), that is, when it is determined that the printing operation is terminated, the temperature control processing program is terminated.

Subsequently, in S11, the control device 51 determines whether or not the currently set on information is the on information of the pattern A.

Then, when it is determined that the currently set on information is the on information of the pattern A (S11: YES), the process proceeds to S4. On the other hand, when it is determined that the currently set on information is the on information of the pattern B (S11: NO), the process proceeds to S6.

On the other hand, in S12, the control device 51 determines whether or not the currently set ON information of the pattern B has the maximum phase (the second ratio is the largest) in the group to which the ON information belongs.

Then, when it is determined that the currently set ON information of the pattern B has the maximum phase in the group to which the ON information belongs (S12: YES), the process proceeds to S13. On the other hand, when it is determined that the currently set ON information of the pattern B is not the maximum phase in the group to which the ON information belongs (S12: NO), the process proceeds to S14.

In S13, the control device 51 switches to the on information of the pattern A having the largest phase in the same group to which the currently set on information belongs. After that, it shifts to S10.

On the other hand, in S14, the control device 51 switches to the on information of the pattern B having a larger phase in the same group to which the currently set on information belongs. It should be noted that the on information of the pattern B whose phase is only one step larger than the current on information may be switched, or the on information of the pattern B corresponding to the current temperature difference (that is, the phase is 2 than the current on information). You may switch to on-information that is larger than the stage. After that, it shifts to S10.

Further, in S15, the control device 51 determines whether or not the temperature of the fixing unit 19 has dropped to the temperature corresponding to the on information of the pattern A of the group in which the wave number is one step larger than that of the group to which the on information currently set belongs. do. For example, when the on information of the pattern A of the group 6 shown in FIG. 4 is set, it is determined whether or not the temperature has dropped to the target temperature of -20.5 ° C., which is the temperature corresponding to the on information of the pattern A of the group 5. Will be done.

Then, when it is determined that the temperature of the fixing unit 19 has dropped to the temperature corresponding to the on information of the pattern A of the group in which the wave number is one step larger than that of the group to which the on information currently set belongs (S15: YES). Moves to S16. On the other hand, when it is determined that the temperature of the fixing unit 19 has not dropped to the temperature corresponding to the on information of the pattern A of the group in which the wave number is one step larger than that of the group to which the on information currently set belongs (S15). : NO) shifts to S17.

In S16, the control device 51 switches to the on information of the pattern A of the group in which the wave number is one step larger than the group to which the on information currently set belongs. For example, when the on information of the pattern A of the group 6 shown in FIG. 4 is set, it is switched to the on information of the pattern A of the group 5. After that, it shifts to S10.

After that, in S17, the control device 51 before the temperature of the fixing unit 19 drops to the temperature corresponding to the on information of the pattern A of the group in which the wave number is one step larger than that of the group to which the on information currently set belongs. Determine if it has become stable. For example, when the on information of the pattern A of the group 6 shown in FIG. 4 is set, the target temperature higher than the target temperature -20.5 ° C., which is the temperature corresponding to the on information of the pattern A of the group 5. This applies to cases where the temperature stabilizes (does not drop below that level) at around 18 ° C to -19 ° C.

Then, when it is determined that the temperature of the fixing unit 19 is stable before falling to the temperature corresponding to the on information of the pattern A of the group in which the wave number is one step larger than that of the group to which the on information currently set belongs (S17). : YES), the process proceeds to S18. On the other hand, when it is determined that the temperature of the fixing portion 19 is not stable (S17: NO), the process proceeds to S3.

In S18, the control device 51 switches to the ON information of the pattern B corresponding to the stable detection temperature in the group in which the wave number is one step larger than the group to which the ON information currently set belongs. For example, when the on information of the pattern A of the group 6 shown in FIG. 4 is set and the temperature stabilizes after the target temperature of the fixing portion 19 drops to -19 ° C, the pattern B of the group 5 is turned on. Among the information, switch to on information corresponding to the target temperature -19 ° C. After that, it shifts to S10.

The mode of switching on information when each of the processes S1 to S18 described above is executed will be described below with two specific examples.
For example, in the first example shown in FIG. 7, the detection temperature is lowered when the on information of the pattern A of the group 7 is set first. In such a case, the temperature is waited to drop to the temperature (target temperature −17 ° C.) corresponding to the ON information of the pattern A of the group 6, and then the ON information of the pattern A of the group 6 is switched. Therefore, when the on-information is switched, the phase does not change (10% before and after the switching), so that flicker can be suppressed.
Further, when the detection temperature rises after the ON information of the pattern A of the group 6 is set, the ON information of the pattern B having a smaller phase among the ON information belonging to the same group 6 is switched. Therefore, when the on-information is switched, the wave number does not change and the phase does not change significantly (only 1% changes even if the phase is lowered by one step), so that flicker can be suppressed and temperature ripple can be reduced.
After that, as the detected temperature rises, the on information having a smaller phase is gradually switched to, and when the temperature finally stabilizes, the on control corresponding to the stable temperature is set. In the control combining wave number control and phase control as in the present embodiment, a steep current does not flow, so that harmonics can be suppressed.

On the other hand, in the second example shown in FIG. 8, the detection temperature rises when the on information of the pattern A of the group 7 is set first. In such a case, the on information of the pattern B having a smaller phase of the same group 7 is gradually switched. Therefore, when the on-information is switched, the wave number does not change and the phase does not change significantly (only 1% changes even if the phase is lowered by one step), so that flicker can be suppressed and temperature ripple can be reduced.
After that, if the detection temperature rises further after the ON information of the pattern B having the smallest phase in the group 7 is set, the ON information of the pattern A of the group 8 is switched.
After that, when the temperature finally stabilizes, the on control corresponding to the stable temperature is set. In the control combining wave number control and phase control as in the present embodiment, a steep current does not flow, so that harmonics can be suppressed.

Incidentally, in the present embodiment, the printer 10 is an example of an "image forming apparatus".

[Effect of Examples]
According to the above-described embodiment, the following effects are obtained.

When the control device 51 sets the on information of the pattern A in which the second ratio is the maximum value among the on information included in any of the groups and the detection temperature drops, the control device 51 is more than the present. The current on information is maintained and set until the temperature corresponding to the on information of pattern A at which the second ratio becomes the maximum value among the on information included in the group in which the wave number is one step larger is reached, and the temperature is set to the corresponding temperature. After reaching it, switch to the on information and set. As a result, it is possible to prevent the phase from changing significantly due to the switching of the off information to be set, and to suppress temperature ripple and flicker.

The control device 51 is a case where the detection temperature drops while the on information of the pattern A in which the second ratio is the maximum value is set among the on information included in any of the groups, and the detection temperature. If is stable before reaching the temperature corresponding to the on information of pattern A in which the second ratio is the maximum value among the on information included in the group in which the wave number is one step larger than the present, the detection temperature becomes stable. Switch to the corresponding on control and set. As a result, even when the detected temperature is stable during the decrease, it is possible to switch to the off information according to the stable temperature.

When the control device 51 sets the on information of the pattern A in which the second ratio is the maximum value among the on information included in any of the groups and the detection temperature rises, the control device 51 is assigned to the same group. Of the included on-information, the second ratio is switched to the on-information whose value is smaller than the maximum value and set. Further, when the detection temperature rises further after that, the second ratio is gradually switched to the on-information and set. As a result, it is possible to prevent the phase and wave number from changing significantly due to the switching of the off information to be set, and to suppress temperature ripple and flicker.

When the detection temperature rises when the control device 51 sets the on information in which the second ratio is the minimum value among the on information included in any of the groups, the wave number is 1 than the present. It is set by switching to the on information of the pattern A in which the second ratio is the maximum value among the on information included in the small group. As a result, it is possible to prevent the phase and wave number from changing significantly due to the switching of the off information to be set, and to suppress temperature ripple and flicker.

When the detection temperature drops when the control device 51 sets the on information of the pattern B in which the second ratio is the third value smaller than the maximum value among the on information included in any of the groups. Is set by switching to the on information in which the second ratio is the fourth value larger than the third value among the on information included in the same group. As a result, it is possible to prevent the phase and wave number from changing significantly due to the switching of the off information to be set, and to suppress temperature ripple and flicker.

The control device 51 sets only the on information of the pattern A in which the second ratio becomes the maximum value in each group until the detected temperature reaches the target temperature or the temperature ripple becomes equal to or less than the threshold value. As a result, it becomes possible to quickly reach the target temperature.

Further, in the temperature table, the maximum value of the second ratio is 10% or less, and the ratio of the first period to the half cycle of the AC power supply is 90% or more, so that the phase does not change significantly, so that flicker can be suppressed. .. In addition, harmonics can be suppressed without a steep current flowing.

[Change example]
The present invention is not limited to the above embodiment, and various modifications can be made without departing from the spirit of the present invention.
For example, in the present embodiment, when the wave number control and the phase control are combined, as shown in FIG. 9, the phase control that controls the half wave in the off state of the wave number control to be turned on at an arbitrary phase angle in the half wave is performed. Although it is combined, the following control is also possible.
(Modification 1) A pattern in which a half wave in a wave number control off state is combined with an antiphase control that controls off at an arbitrary phase angle within the half wave.
(Modification 2) Instead of wavenumber control, phase control that controls on at any phase angle in the half wave is inserted, and for half wave in the off state, control is turned on at any phase angle in the half wave. A pattern that combines phase control.
(Modification 3) Instead of wave number control, phase control that controls on at any phase angle in the half wave is inserted, and for half wave in the off state, control is turned off at any phase angle in the half wave. A pattern that combines anti-phase control.
(Modification example 4) Instead of wavenumber control, anti-phase control that controls off at any phase angle in the half wave is inserted, and for the half wave in the off state, it is turned on at any phase angle in the half wave. A pattern that combines phase control to control.
(Modification 5) Instead of wavenumber control, anti-phase control that controls off at any phase angle in the half wave is inserted, and for the half wave in the off state, it is turned off at any phase angle in the half wave. A pattern that combines anti-phase control to control.

Further, in the present embodiment, the temperature table shown in FIG. 4 is used, but the number of off information and the number of groups included in the temperature table can be changed as appropriate.

10 Printer 19 Fixing part 49 Heater 51 Control device 59 Switching element P sheet

Claims (11)

A heater that is heated by the power supplied from an AC power supply, and
A fixing portion provided with the heater and fixing an image of toner formed on the sheet, and a fixing portion.
A switching element provided between the AC power supply and the heater to switch between an on state in which the AC power supply and the heater are conductive and an off state in which the AC power supply and the heater are not conductive.
A temperature sensor that outputs a signal according to the temperature of the fixing portion, and
A table corresponding to on information, which is information indicating a period during which the switching element is turned on in the control cycle, is stored for each different temperature, with a plurality of continuous half waves of the waveform of the AC power supply as the control cycle. Memory and
With reference to the table, the on information corresponding to the detection temperature, which is the temperature of the fixing portion detected based on the signal input from the temperature sensor, is set, and the period indicated by the set on information is described. A control device for controlling the switching element so that the switching element is turned on is provided.
The on information is
The first information indicating one or more half waves in which the switching element is turned on for the first period among the plurality of half waves constituting the control cycle, and
Second information indicating the first ratio, which is the total ratio of the first period in each half wave indicated by the first information, with respect to the control cycle.
The second period in which the switching element is turned on in each of one or a plurality of half waves other than the half wave indicated by the first information among the plurality of half waves constituting the control cycle. A third piece of information indicating the second period, which is shorter than the first period,
Includes fourth information indicating the second ratio, which is the total ratio of the second period in each half wave indicated by the third information, to the control cycle.
The table
A first group containing a plurality of the on-information, wherein the first ratio indicated by the second information is a first value to each other and the second ratio indicated by the fourth information is different from each other.
A second value containing a plurality of the on-information in which the first ratio indicated by the second information is a second value larger than the first value and the second ratio indicated by the fourth information is different from each other. Divided into 2 groups
The control device is
If the detection temperature drops while the on information in which the second ratio is the maximum value of the on information included in the first group is set, the on information included in the second group is included. An image forming apparatus that sets the on-information in which the second ratio of the information is the maximum value. The control device is
If the detection temperature drops while the on information in which the second ratio is the maximum value is set among the on information included in the first group, the detection temperature is included in the second group. The current on information is maintained and set until the temperature corresponding to the on information at which the second ratio becomes the maximum value is reached.
The image forming apparatus according to claim 1, wherein after reaching the temperature, the on-information included in the second group is switched to the on-information in which the second ratio becomes the maximum value. The control device is
When the detection temperature drops while the on information in which the second ratio is the maximum value is set among the on information included in the first group, the detection temperature is set to the second group. When the detection temperature stabilizes before reaching the temperature corresponding to the on information at which the second ratio of the included on information becomes the maximum value,
The image forming apparatus according to claim 2, wherein among the on-information included in the second group, the on-control corresponding to a stable detection temperature is switched and set. The control device is
If the detection temperature rises while the on-information in which the second ratio is the maximum value is set among the on-information included in the second group, the on-information included in the second group is included. The image forming apparatus according to any one of claims 1 to 3, wherein the on information is set by switching to the on information in which the second ratio is the first value smaller than the maximum value. The control device is
If the detection temperature rises while the on-information in which the second ratio is the first value among the on-information included in the second group is set, it is included in the second group. The image forming apparatus according to claim 4, wherein the on-information is set by switching to the on-information in which the second ratio is a second value smaller than the first value. The control device is
If the detection temperature rises while the on-information in which the second ratio is the minimum value is set among the on-information included in the second group, the on-information included in the first group is included. The image forming apparatus according to any one of claims 1 to 5, wherein the on information is set by switching to the on information in which the second ratio is the maximum value. The control device is
If the detection temperature drops while the on information is set so that the second ratio is a third value smaller than the maximum value among the on information included in the second group, the second The image formation according to any one of claims 1 to 6, wherein the on-information included in the group is switched to the on-information in which the second ratio is a fourth value larger than the third value. Device. The control device is
Claims 1 to 7 in which only the on-information in which the second ratio becomes the maximum value is set in each group until the detected temperature reaches the target temperature or the temperature ripple becomes equal to or lower than the threshold value. The image forming apparatus according to any one. The image forming apparatus according to any one of claims 1 to 8, wherein the maximum value of the second ratio is 10% or less. The image forming apparatus according to any one of claims 1 to 9, wherein the ratio of the first period to the half cycle of the AC power supply is 90% or more. The control device is
The on state of the switching element continues from the on state of the switching element due to the zero cross timing at which the half wave indicated by the first information starts until the zero cross timing at which the half wave indicated by the first information ends. The image forming apparatus according to claim 10, wherein the switching element is controlled as described above.

Images