JP2018022037A - Heating device, image forming apparatus, and control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a heating device that, when power supply is unstable, can appropriately perform power supply to heating means that heats a sheet.SOLUTION: A fixing belt unit 200 heats a sheet M. A control part 403, when determining abnormality in power supply voltage provided by a power supply unit 400 during first power supply to the fixing belt unit 200 performed when the fixing belt unit 200 starts heating, stops the first power supply. The control part waits a standby time according to the state of the power supply voltage provided by the power supply unit 400 during the first power supply before performing second power supply.SELECTED DRAWING: Figure 3

Description

  The present invention relates to a heating device that heats a sheet and an image forming apparatus including the same.

  A heating device for heating a sheet has been developed. Patent Document 1 discloses a fixing device that heats a sheet by a nip in which a pressure roller is pressed against a fixing roller incorporating a lamp heater. Here, whether to stop the power supply to the lamp heater is determined based on the temperature of the fixing roller and the temperature of the pressure roller detected at the start of the power supply to the lamp heater at the start of heating of the lamp heater. .

JP 2001-242740 A

  In the fixing device, if the temperature does not rise to the target temperature within a predetermined time after the start of power supply, it is determined that there is an abnormality and the power supply is temporarily stopped. At this time, the power supply voltage may be lower than the rated voltage. In this case, the second power supply is automatically executed after a certain waiting time to wait for the power supply voltage to recover. It is desirable to do (retry). However, when a uniform waiting time is used, if the waiting time is too long, the start of use of the fixing device is delayed. On the other hand, if the standby time is too short, the power supply voltage cannot be recovered in time, and the second power supply is likely to be stopped because the power supply voltage is lower than the rated voltage. When power supply retries are repeated in this way, the power consumption of the heater increases, so it is desirable that the number of retries is small and the standby time is short.

  An object of this invention is to provide the heating apparatus which can perform the electric power supply to the heating means which heats a sheet | seat appropriately.

  The heating device of the present invention includes a heating unit that heats a sheet, a determination unit that determines a temperature change state during heating of the heating unit, and a time corresponding to the temperature change state determined by the determination unit. Control means for supplying power again to the heating means after stopping the power supply to the means.

  Further, the heating device of the present invention includes a heating unit that heats the sheet, and a control unit that supplies power to the heating unit after a lapse of time according to the state of a power source after stopping power supply to the heating unit. It is to be prepared.

  ADVANTAGE OF THE INVENTION According to this invention, the heating apparatus which can perform the electric power supply to the heating means which heats a sheet | seat appropriately can be provided.

1 is an explanatory diagram of a configuration of an image forming apparatus. FIG. 4 is an explanatory diagram of a cross-sectional configuration perpendicular to the rotation axis of the fixing device. (A) is a fixing device, and (b) is a fixing belt. FIG. 4 is an explanatory diagram of a cross-sectional configuration along the rotation axis of the fixing device. 2 is a block diagram of a control system of the image forming apparatus. FIG. FIG. 6 is an explanatory diagram of fluctuations in power supply to the fixing belt accompanying fluctuations in power supply voltage. It is explanatory drawing of the temperature rise acceleration of a fixing belt. 6 is a flowchart of power supply control for the fixing device at the time of startup. It is a flowchart of retry control. It is explanatory drawing of the waiting time until it starts the 2nd electric power supply. (A) is a temperature rise curve of the fixing belt, and (b) is a rise curve of the power supply voltage.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

<Embodiment 1>
In the first embodiment, the standby time is set according to the temperature increase acceleration (temperature increase rate per unit time) at the first power supply when the fixing device is activated.

(Image forming device)
FIG. 1 is an explanatory diagram of the configuration of the image forming apparatus. As shown in FIG. 1, the image forming apparatus 100 is an electrophotographic monochrome copying machine.

  The image forming unit 120 forms a toner image on the photosensitive drum 2 and transfers the toner image to the sheet M passing through the transfer unit T1. The image forming unit 120 includes a charging roller 3, an exposure device 1, a developing device 4, a transfer roller 12, and a drum cleaning device 5 around the photosensitive drum 2.

  The photosensitive drum 2 rotates with a photosensitive layer formed on the circumferential surface of a metal cylinder. The charging roller 3 is applied with an oscillating voltage obtained by superimposing an AC voltage on a DC voltage, and charges the photosensitive drum 2 to a uniform potential. The exposure apparatus 1 drives a semiconductor laser with an image signal obtained by ON-OFF modulating a scanning line signal obtained by developing image data, generates a laser beam, scans the laser beam with a rotating mirror, and records an image on the photosensitive drum 2. An electrostatic latent image is formed.

  The developing device 4 carries a developer (magnetic toner) on the developing roller 4a and develops the electrostatic latent image on the photosensitive drum 2 into a toner image. The transfer roller 12 is applied with a DC voltage having a polarity opposite to the charging polarity of the toner, and transfers the toner image on the photosensitive drum 2 to a sheet passing through the transfer portion T1.

  A paper feeding unit 130 is disposed below the image forming apparatus 100. The sheet feeding unit 130 stores the sheet P in the cassette 6. The pickup roller 7 feeds the sheet P from the cassette 6 and feeds it to the separation unit 8. The separation unit 8 separates the multi-feed sheet and feeds only the uppermost sheet M to the registration roller 11. The registration roller 11 corrects the skew of the sheet M, and feeds the sheet M to the transfer unit T1 in synchronization with the toner image on the photosensitive drum 2.

  The fixing device 110, which is an example of a heating device, heats the sheet on which the toner image is transferred by the image forming unit 120. The sheet M on which the toner image is transferred by the transfer unit T1 is conveyed to the fixing device 110, and is heated and pressurized in the process of being conveyed by the nip N, and the image is fixed on the surface. The sheet M on which the image is fixed at the nip N is conveyed to the discharge unit 140, is nipped by the discharge roller 14, is discharged to the discharge tray 16, and is stacked.

(Fixing device)
FIG. 2 is an explanatory diagram of a cross-sectional configuration perpendicular to the rotation axis of the fixing device. FIG. 3 is an explanatory diagram of a cross-sectional configuration along the rotation axis of the fixing device. In FIG. 2, (a) is a fixing device, and (b) is a fixing belt. FIG. 3 is a view of the fixing device 110 shown in FIG. 2 as viewed from the sheet discharge side. As shown in FIG. 1, the sheet M on which the toner image is transferred by the image forming unit 120 is conveyed to a fixing device 110 for fixing the toner image.

  As shown in FIG. 2A, the fixing device 110 applies heat to the unfixed toner image on the sheet M as well as pressure. The fixing belt unit 200, which is an example of a heating unit, fixes the image on the sheet M by integrally heating the sheet M and the toner image formed on the sheet M to melt the toner. The fixing device 110 fixes the image on the sheet M by the heat energy generated through the current in the fixing belt 201 and the pressure applied by the pressure roller 208.

  The fixing device 110 forms a nip N by pressing a pressure roller 208 against a fixing belt 201 whose inner peripheral surface is supported by a belt guide 202. As shown in FIG. 2B, the fixing belt 201 is formed by forming an elastic layer 201b of silicon rubber on a heat generating layer 201a serving as a base layer of polyimide resin in which carbon particles are dispersed and resistance is adjusted, and the surface is made of fluorine. An endless belt covered with a release layer 201c of a resin material. The fixing belt 201 is a member having a composite structure.

  The belt guide 202 is formed of a heat resistant resin and supports the inner peripheral surface of the fixing belt 201. A guide surface of the fixing belt 201 is formed on the belt guide 202. The stay 205 is made of mild steel and is disposed through the fixing belt 201 in a beam shape, and supports the belt guide 202 against the pressure applied by the pressure roller 208.

  In the pressure roller 208, an elastic layer 208b of silicon rubber having a thickness of 5 mm is formed around a cored bar portion 208a integrated with the rotation shaft. The elastic layer 208 b is deformed along the surface shape of the belt guide 202 to bring the fixing belt 201 into close contact with the belt guide 202. The surface of the elastic layer 208b is covered with a release layer 208c made of a fluororesin material.

  The pressure roller 208 is rotated in the direction of the arrow R208 by the motor 220. The fixing belt 201 rotates in the direction of the arrow R201 following the rotation of the pressure roller 208 while the inner surface is rubbed against the belt guide 202.

  As shown in FIG. 3, the stay 205 is disposed through the fixing flanges 212 a and 212 b that guide the edge of the fixing belt 201. The pressure springs 217 a and 217 b pressurize both ends of the stay 205 toward the pressure roller 208.

  Both ends of the fixing belt 201 made of a resistance heating material are in contact with fixing flanges 212a and 212b as electrode members.

  The power supply unit 400 applies an AC voltage to both ends of the fixing belt 201 through the fixing flanges 212a and 212b, thereby energizing the fixing belt 201 in the rotation axis direction and causing the fixing belt 201 to generate heat by resistance heating. The heat of the heat generating layer 201a of the fixing belt 201 shown in FIG. 2B is transmitted from the elastic layer 201b to the release layer 201c, and the entire fixing belt 201 is heated. The fixing belt 201 is rapidly heated by application of an AC voltage.

  The thermistors 209, 210, and 211 of the non-contact type thermistors are disposed at positions facing the fixing belt 201 on the side where the sheet M is conveyed to the fixing device 110. The thermistors 209, 210, and 211 detect the temperature facing the fixing belt 201 at different positions in the rotation axis direction of the fixing belt unit 200. The thermistor 209 is disposed at the center in the rotation axis direction, the thermistor 10 is disposed at the left end side in the rotation axis direction, and the thermistor 211 is disposed at the right end side in the rotation axis direction.

  The temperature control unit 404 performs temperature control for adjusting the temperature of the fixing belt 201 toward the target temperature based on the outputs of the thermistors 209, 210, and 211. The temperature control unit 404 performs temperature adjustment using the thermistors 209, 210, and 211 so that the fixing belt 201 becomes a constant temperature. The control unit 403 rotates the pressure roller 208 by the motor 220 in response to the print command. The control unit 403 controls the temperature control unit 404 to apply an AC voltage to the fixing belt 201.

  In a conventional roller heating type fixing device using a halogen lamp heater, the heat capacity of the fixing roller is large and the temperature rise is slow. For this reason, in a conventional roller heating type fixing device, intermittent power supply is performed so as to adjust the temperature of the fixing roller to a constant temperature not only during the period for performing the fixing process but also during the waiting period for the fixing process.

  On the other hand, the fixing device 110 is an on-demand fixing device that heats the fixing belt unit 200 only during a fixing process. In the on-demand fixing device, since the heat capacity of the fixing belt 201 is small and the temperature rises quickly, power is not supplied to the fixing belt 201 during standby for fixing processing. Immediately before the start of the fixing process, power supply to the fixing belt 201 is started and temperature adjustment is performed until the fixing process is completed.

  The temperature control unit 404 detects the temperature of the fixing belt 201 using the thermistors 209, 210, and 211, and adjusts the temperature so as to match the target temperature. This is because the fixing belt 201 maintains the target temperature by making up for the heat taken from the fixing belt 201 to the sheet M when the image is fixed by applying pressure and heat to the sheet M in the nip N.

  Since the fixing belt 201 has a small heat capacity, a temperature change accompanying the fixing process is likely to occur remarkably, and fine control is required to keep the temperature of the fixing belt 201 constant. In the on-demand type fixing device 110, since the heat capacity of the fixing belt 201 is small, it is easily affected by fluctuations in the power supply voltage.

(Control part)
FIG. 4 is a block diagram of a control system of the image forming apparatus. As shown in FIG. 4, the control unit 403 generalizes the image forming apparatus 100 shown in FIG. 1 by holding the data and programs recorded in the ROM 412 in the RAM 413 and executing the necessary calculations and processing by the CPU 411. Control.

  The control unit 403 receives and holds image information sent from an external computer and image information of a document captured by an image reading device (not shown). The control unit 403 performs image processing on the image information to generate an exposure signal, and transmits it to the image forming unit 120 shown in FIG. 1 at a timing linked to image formation.

  An operation panel 420 is disposed above the image forming apparatus. From the operation panel 420, the user can select a copy mode, such as an instruction to start copying, selection of the size of a recording sheet on which an original image is copied, and selection of the number of copies. The operation panel 420 displays various information transmitted from the control unit 403 to the user.

  The detected temperatures of the thermistors 209, 210, and 211 are output to the temperature control unit 404. The temperature control unit 404 controls the alternating current applied to the fixing belt 201 based on the temperature detected by the thermistor 209 disposed at the center of the fixing belt 201 in the rotation axis direction. The temperature control unit 404 controls the power supply unit 400 based on the temperature detected by the thermistor 209, and changes the alternating current that is energized to the fixing belt 201 to maintain the surface temperature of the fixing belt 201 at the target temperature for temperature adjustment. ·adjust.

  The power supply unit 400 adjusts the power supplied to the fixing belt 201 by duty-controlling the power supply voltage of the AC voltage based on the temperature difference between the temperature detected by the thermistor 209 and the target temperature. A thermistor 209 that is an example of a detection unit detects the temperature of the fixing belt unit 200. When the fixing device 110 is activated, the power supply unit 400 supplies the power supply voltage to the fixing belt 201 with a duty ratio of 100% to rapidly raise the temperature of the fixing belt 201. After the fixing belt 201 reaches the target temperature, the temperature of the fixing belt 201 is stabilized by finely changing the power supply voltage with a duty ratio of 10%.

(Power supply circumstances)
When the area where the image forming apparatus 100 is used is an area where the power supply situation is not good, it is difficult to supply a stable power supply voltage, and a power supply voltage state lower than the rated voltage determined by the device on which the image forming apparatus 100 is mounted is generated. There is a case.

  When the low power supply voltage state continues, or when the power supply voltage temporarily changes from the rated voltage to return to the rated voltage, there is a possibility that the power supply to the fixing belt 201 is insufficient when the fixing device 110 is started up. There is. As a result, the detected temperature of the thermistor 209 may not reach a preset threshold temperature within a certain time after the start of power supply to the fixing belt 201.

(Service man call)
When the fixing device 110 is started up, the control unit 403 activates the fixing device 110 or the power supply if the temperature detected by the thermistor 209 does not reach a preset threshold temperature within a certain time after the start of power supply to the fixing belt 201. It is determined that an abnormality has occurred in unit 400. When the controller 403 determines that an abnormality has occurred, it stops heating the fixing belt 201 and displays an error on the operation panel 420.

  The control unit 403 monitors the temperature control of the fixing belt 201 by the temperature control unit 404. When heating the fixing belt 201, the control unit 403 stops heating the fixing belt 201 and displays an error on the operation panel 420 even if the temperature detected by the thermistor 209 rises above a preset upper limit temperature.

  The control unit 403 may be treated as a service man call in which the user cannot remove the prohibition of image formation in consideration of the expertise of error recovery work. In this case, if there is a problem with the device mounted on the image forming apparatus 100 as the cause of the error, the process of handling as a service man call is appropriate. However, if the fixing belt 201 cannot be heated to the target temperature due to an external factor, for example, the voltage situation in the area is unstable and the rated voltage cannot be maintained, it is treated as a service man call. The process is unjustified. This is because there is no problem with the devices mounted on the image forming apparatus 100, and it is useless to call a service person when the cause of the error is eliminated simply by waiting for recovery of the power supply voltage.

  Accordingly, when the first power supply to the fixing belt 201 is performed and the target temperature is not reached within a certain time, the second power supply is performed to the fixing belt 201 after a certain waiting time. Control was proposed. If the error is resolved by the second power supply, the image forming apparatus 100 is allowed to be used as it is, and if the error is reproduced by the second power supply, it is treated as a serviceman call.

  However, when the second power supply to the fixing belt 201 is performed after a certain waiting time, if the waiting time is too long, the start of use of the image forming apparatus 100 is delayed, which is not preferable. However, if the standby time is too short, the power supply voltage is not sufficiently recovered by the second power supply, and the error is reproduced by the second power supply.

  Therefore, in the first embodiment, the standby time is variably set by evaluating the temperature rise acceleration of the fixing belt 201 in the first power supply and estimating the recovery time of the power supply voltage. Thereby, when the power supply voltage does not satisfy the rated voltage, a highly accurate standby time is set, and the probability that the fixing belt 201 reaches the target temperature within a predetermined time by the second power supply is increased. An error was repeated in the second power supply so that the service man call was not processed.

(Temperature rise acceleration)
FIG. 5 is an explanatory diagram of fluctuations in power supply to the fixing belt accompanying fluctuations in the power supply voltage. FIG. 6 is an explanatory diagram of the temperature increase acceleration of the fixing belt. As shown in FIG. 3, when the power supply unit 400 applies an AC voltage to the fixing belt 201, the fixing belt 201 generates heat and the temperature of the fixing belt 201 rises.

As shown in FIG. 5, when the power supply voltage applied to the fixing belt 201 fluctuates, assuming that the resistance value of the fixing belt 201 is constant, the power supplied to the fixing belt 201 is the following according to Ohm's law: Can be expressed as follows.
W = V2 / R
W: Heater power V: Input AC voltage R: Heater resistance

  That is, when the power supply voltage applied to the fixing belt 201 varies, the power supplied to the fixing belt 201 varies with the square of the power supply voltage. Therefore, as shown in FIG. 6, when the power supply voltage recovers in a linear function toward the rated voltage of 100 V, the power supplied to the fixing belt 201 increases in a quadratic function. At this time, the transition of the temperature rise at the start-up of the fixing device 110 is not a linear function but a curve of a quadratic function. When the power supply voltage recovers in a linear function and the heating energy supplied to the fixing belt 201 increases in a quadratic function, the temperature increase rate of the fixing belt 201 changes at an acceleration.

  Here, α represents the temperature increase acceleration of the fixing belt 201 in the first power supply. The temperature rise acceleration α is a change rate of the temperature rise speed. The temperature increase acceleration is a representation of the temperature increase amount per unit time as a speed, and is a difference in the temperature increase amount per unit time. The temperature rise acceleration α is an average value of the rate of change in the amount of rise in temperature detected by the thermistor 209 per unit time. Specifically, it is the difference between the amount of increase in temperature 1-2 seconds after the start of power supply and the amount of increase in temperature 0-1 seconds after the start of power supply.

  As shown in FIG. 6, when α> 0, the temperature of the fixing belt 201 rises along a curve of a quadratic function that becomes steeper as the temperature rise acceleration α increases. The higher the heating energy is applied due to fluctuations in the power supply voltage, the greater the rate of temperature rise detected by the thermistor 209, and the temperature gradient with respect to time of the temperature detected by the thermistor 209 becomes steeper. On the other hand, the lower the heating energy is applied, the lower the temperature rise rate of the temperature detected by the thermistor 209, and the temperature gradient with respect to time of the temperature detected by the thermistor 209 becomes gentler.

  On the other hand, when α = 0, the power supply voltage does not fluctuate, and the temperature rise curve of the fixing belt 201 is a straight line having a constant slope. In the first embodiment, when the input voltage is fixed, control is performed so that the gradient of temperature rise is a straight line (temperature rise acceleration α = 0). On the other hand, although not shown, when α <0, the slope of the temperature rise curve of the fixing belt 201 decreases with time as in a logarithmic curve.

  When an AC voltage with a duty ratio of 100% is continuously applied to the fixing belt 201, the resistance of the fixing belt 201 increases as the temperature rises. However, since the increase in the supply power due to the increase in the power supply voltage contributes more to the amount of power supply than the decrease in the supply power due to the temperature coefficient of the resistance value, the fluctuation range of the supply power due to the increase in the resistance value is Can be ignored. Alternatively, it can be dealt with by a slight shift of the threshold value of the target temperature.

  In the first embodiment, when the first power supply is stopped when the fixing device 110 is started, the temperature increase acceleration α of the temperature increase curve of the fixing belt 201 is calculated, and the second time according to the temperature increase acceleration α. The standby time until the start of power supply (retry) is determined. In the first embodiment, when the first power supply is stopped when the fixing device 110 is started, the factor on the image forming apparatus side and the factor on the power supply voltage side are separated according to the temperature rise acceleration α. In the first embodiment, it is assumed that the power supply voltage rises to the rated voltage when the standby time elapses from a state where the power supply voltage is lower than the rated voltage. Judging whether to rise to.

(Power supply control to the fixing device at startup)
FIG. 7 is a flowchart of power supply control for the fixing device at the time of startup. FIG. 8 is a flowchart of retry control.

  As shown in FIG. 7 with reference to FIG. 4, the control unit 403, which is an example of a control unit, corrects the power supply voltage abnormality in the first power supply to the fixing belt unit 200 that is performed when heating of the fixing belt unit 200 is started. When it is determined, the first power supply is stopped.

  When the user turns on the image forming apparatus 100, the power supply unit 400 is activated (S101). When the power supply unit 400 is activated, the CPU 411 resets the control unit 403 (S102). When the control unit 403 is reset, the engine control unit 401 starts each control.

  The CPU 411 controls the power supply unit 400 through the temperature control unit 404 and starts supplying power to the fixing belt 201 (S103). The CPU 411 determines whether or not the temperature reaches the preset target temperature within a predetermined time while recording the temperature of the fixing belt 201 through the temperature control unit 404 (S104).

  When the temperature of the fixing belt 201 reaches the target temperature within a predetermined time (YES in S104), the CPU 411 shifts to a normal image forming sequence (S106) and ends the power supply control to the fixing device at the time of activation. . If the temperature of the fixing belt 201 does not reach the target temperature within a predetermined time (NO in S104), the CPU 411 executes a “retry control” subroutine (S105), and then proceeds to a normal image forming sequence (S105). S106).

As shown in FIG. 8 with reference to FIG. 4, the CPU 411 performs a calculation process of the temperature increase acceleration in the first power supply (S103) (S201). The temperature increase acceleration is calculated by repeatedly calculating a temperature change amount (temperature increase rate) per unit time and obtaining a difference for each unit time. Let the calculated temperature rise acceleration be α [Δ ° C./sec ² ]. As described above, in the first embodiment, the temperature increase acceleration α is, for example, as a difference between the temperature increase amount of 1-2 seconds after the start of power supply and the temperature increase amount of 0-1 seconds after the power is turned on as follows. Looking for.

α = (10 ° C./sec−6° C./sec)/1 sec = 4 ° C./sec ²
The CPU 411 determines the contents of the retry control according to the temperature increase acceleration α that is the average value of the rate of change of the temperature increase per unit time detected by the thermistor 209 in the first power supply. For example, when the temperature increase acceleration α is 4 ° C./sec ² , the standby time is 90 seconds. If the temperature rise acceleration α of ^{4 ℃ / sec 2 8 ℃ /} sec 2 greater than the standby time is 60 seconds shorter than 90 seconds.
Acceleration α <0: Standby time 120 seconds + Retry execution acceleration α = 0: Error sequence acceleration 0 <α ≦ 5: Standby time 90 seconds + Retry execution acceleration 5 <α ≦ 10: Standby time 60 seconds + Retry execution acceleration 10 < α: Standby time 30 seconds + retry execution

  The CPU 411 determines whether or not the temperature increase acceleration α is 0 (S202). If the temperature increase acceleration α is 0 (YES in S202), the CPU 411 indicates that the AC voltage has not increased and the temperature of the fixing belt 201 has not reached the target temperature within a predetermined time. It is determined that the image forming apparatus is on the side. Therefore, the process proceeds to a preset error sequence without executing a retry (S212). In the error sequence, an error process for handling a serviceman call is designated on the operation panel 420 as a heater disconnection, a thermistor breakage, or a power supply unit 400 failure. Image formation is prohibited and a service man is called to instruct parts to be replaced. When the temperature increase acceleration in the first power supply is 0, the second power supply is prohibited.

  As shown in FIG. 7, even when the temperature increase acceleration α = 0, when the temperature of the fixing belt 201 is increased to the target temperature within a predetermined time (YES in S104), the power supply voltage is rated. The voltage is determined to be shifted to a normal image forming sequence (S106).

  However, if the temperature of the fixing belt 201 has not increased to the target temperature within a predetermined time (NO in S104), it is difficult to consider that the power supply voltage is abnormal if the temperature increase acceleration α = 0. Therefore, it is immediately determined that there is an abnormality on the fixing device 110 side without executing a retry (S202).

  That is, the control unit 403 prohibits power supply when the temperature increase acceleration α is zero. Since the power supply voltage fluctuates when the power supply voltage is lower than the rated voltage, the state where the temperature rises only in the same width does not last long. When the temperature increase acceleration is 0, this is an extremely rare case, and it has been confirmed that the disconnection of the sensor or the disconnection of the power supply system has occurred with a high probability. In the case of a disconnection factor, it is not necessary to wait for the waiting time because it is the same regardless of the retry.

  When the temperature increase acceleration α is not 0 (NO in S202), the CPU 411 determines whether or not the temperature increase acceleration α is in the range of more than 0 and less than 5 (S203). When the temperature increase acceleration α is in the range of more than 0 and 5 or less (YES in S203), the CPU 411 sets the standby time to 90 sec (S204).

  When the temperature increase acceleration α is in the range of more than 5 and 10 or less (YES in S205), the CPU 411 sets the standby time to 60 seconds (S206). When the temperature increase acceleration α exceeds 10 (YES in S207), the CPU 411 sets the standby time to 30 seconds (S208). As will be described later, if the temperature rise acceleration α exceeds 0, the power supply voltage has risen, and if it waits for the standby time corresponding to the temperature rise acceleration α, there is a high possibility that it will recover to the rated voltage. A retry which is the second power supply is executed.

  When the temperature increase acceleration α is less than 0 (NO in S207), the CPU 411 sets the standby time to 120 seconds (S209). When the temperature increase acceleration α is less than 0, the power supply voltage is decreasing, so it is difficult to predict when the power supply voltage will recover to the rated voltage, so the longer 120 seconds is set. However, if the power supply voltage does not recover, there is a high possibility that an error will occur again even if retry is executed.

  The CPU 411 waits for the end of each waiting time (S204, S206, S208, S209) and starts the second power supply (S210). The CPU 411 supplies power to the fixing belt 201 for the second time while monitoring the temperature of the fixing belt 201, and determines whether or not the target temperature is reached within a preset predetermined time (S211).

  If the target temperature is not reached within a predetermined time even in the second power supply (NO in S211), the CPU 411 proceeds to a preset error sequence without executing a retry (S212). When the CPU 411 reaches the target temperature within a predetermined time in the second power supply (YES in S211), the CPU 411 determines that the power supply voltage has been restored and proceeds to a normal image forming sequence (S106).

  In the first embodiment, as a result of retrying after a standby time in which the power supply voltage estimated from the temperature rise acceleration α can be recovered to the rated voltage, if the power supply voltage has recovered to the rated voltage as estimated, the retry is successful. For this reason, the control unit 403 determines that the first stop of the power supply is caused by a voltage abnormality. On the other hand, when the retry is unsuccessful and the temperature abnormality is detected again, the control unit 403 determines that the failure of the fixing belt unit 200 is the cause of the first stop of power supply afterwards.

(Setting standby time)
FIG. 9 is an explanatory diagram of the standby time until the second power supply is started. In FIG. 9, (a) is a temperature rise curve of the fixing belt, and (b) is a power supply voltage rise curve.

  As shown in FIG. 9A, in the image forming apparatus 100, an experiment was performed in which the first power supply was performed while increasing the power supply voltage from 80 V at three types of temperature increase rates. In either case, the temperature of the fixing belt 201 did not reach the target temperature of 200 ° C. within 3 seconds of the predetermined time.

  As illustrated in FIG. 3, the control unit 403, which is an example of a determination unit, executes a determination process to determine the state of temperature change during heating of the fixing belt unit 200. In the determination step, the temperature increase acceleration α, which is an example of the temperature increase rate detected by the thermistor 209, is determined as the temperature change state.

  The control unit 403, which is an example of a control unit, executes a power supply process, stops supplying power to the fixing belt unit 200 for a time corresponding to the determined temperature change state, and then supplies power to the fixing belt unit 200 again. I do. In the power supply process, power supply to the fixing belt unit 200 is stopped for a time corresponding to the temperature increase acceleration α.

  When the temperature detected by the thermistor 209 does not reach the target temperature within a predetermined time, the control unit 403 stops the power supply to the fixing belt unit 200 for a time corresponding to the temperature increase acceleration α. The time for stopping the power supply to the fixing belt unit 200 is set shorter as the temperature increase acceleration α is higher.

  As described above, in the first embodiment, the first power supply is interrupted in a predetermined time (3 seconds). However, here, in order to acquire the temperature rise data in the first power supply, the power supply to the fixing belt 201 is continued until the temperature of the fixing belt 201 reaches 70 ° C. even after a predetermined time of 3 seconds elapses. did.

As shown in FIG. 9B, in the image forming apparatus 100, the temperature increase acceleration α measured when the power supply voltage is increased from 80 V is 10 ° C./sec ² , 5 ° C./sec ² , 2.5 ° C. In the case of / sec ^2, an experiment was conducted to determine how many seconds each time the rated voltage was restored to 100 V.
(1) When the voltage increase acceleration α is 10 ° C./sec ² , it has been found that the rated voltage is restored to 100 V in 20 seconds from the start of power supply. Therefore, in Embodiment 1, the standby time is set to 30 seconds.
(2) When the voltage increase acceleration α is 5 ° C./sec ² , it was found that the rated voltage is restored to 100 V in 40 sec from the start of power supply. Therefore, in the first embodiment, the standby time is set to 60 sec.
(3) When the voltage rise acceleration α is 2.5 ° C./sec ² , it has been found that the rated voltage is restored to 100 V in 80 seconds from the start of power supply. Therefore, in the first embodiment, the standby time is set to 90 seconds. .

As shown in FIG. 9A, when the voltage rise acceleration α is 10 ° C./sec ² , 5 ° C./sec ² , 2.5 ° C./sec ² , 20 sec, 40 sec, and 80 sec standby respectively obtained by experiments. A second power supply was performed after some time. In any case, since the power supply voltage has recovered to the rated voltage of 100 V, the temperature of the fixing belt 201 has reached the target temperature of 200 ° C. in about 2 seconds from the start of power supply.

  Based on such experimental results, in the first embodiment, when the power supply voltage is increased by the first power supply, the control unit 403 determines when to recover to the rated voltage by the temperature increase acceleration α. Estimated. For example, when it is determined that the power supply voltage should reach the rated voltage after 80 seconds, the standby time is set to 90 seconds with a margin. As described above, since the retry is executed in accordance with the estimated recovery time of the power supply voltage, it is possible to set an appropriate standby time rather than setting a uniform standby time.

(Effect of Embodiment 1)
In the first embodiment, the second power supply is automatically performed with a standby time corresponding to the state of the power supply voltage in the first power supply. For this reason, the probability that the second power supply can be started with the power supply voltage sufficiently recovered increases. By starting the second power supply in a state where the power supply voltage has sufficiently recovered, it is possible to avoid setting an excessive standby time and increasing the downtime of the image forming apparatus 100. At the same time, it is less likely that the power supply is stopped again by executing the second power supply in a state where the recovery of the power supply voltage is insufficient.

  If the AC voltage is less than the rated voltage, the target temperature may not be reached.

  In the first embodiment, it is possible to avoid an unnecessary error that repeatedly causes a heater abnormality due to temperature failure. Every time a retry is made, power is consumed. It takes time to set a long standby time. In the first embodiment, since a standby time during which a retry will be successful is set, in many cases, the image forming apparatus 100 can be activated by one retry.

  In the first embodiment, after stopping the first power supply, the second power supply is started after a sufficient waiting time. For this reason, the fixing belt 201 can be prevented from being heated beyond the target temperature as in the case where the fixing belt 201 is inadvertently heated many times without waiting. If the power supply is repeatedly turned ON / OFF finely for the fixing belt 201, the temperature of the fixing belt 201 rises in a stepped manner, and the possibility that the fixing belt 201 is heated beyond the target temperature increases. If retry is repeated, an error occurs that the temperature of the fixing belt 201 rises more than necessary.

  For this reason, the second power supply can be executed in an appropriate standby time without the fixing belt 201 being heated exceeding the target temperature. An appropriate standby time is set according to the calculation result reflecting the temperature transition at the time of power supply to the fixing belt 201, and stable fixing performance and long life can be achieved.

  In the first embodiment, the abnormality of the power supply voltage in power supply unit 400 is determined based on the output of the thermistor 209 in the first power supply. Therefore, it is possible to determine an abnormality in the power supply voltage without using a circuit or program for measuring the power supply voltage. A fixing device capable of executing a retry in an appropriate standby time and an image forming apparatus using the fixing device can be realized with a simple configuration at low cost.

  In the first embodiment, the standby time is set based on the output of the thermistor 209 in the first power supply. In the first embodiment, the standby time is set based on the temperature rise state detected by the thermistor 209 in the first power supply. For this reason, it is possible to set the standby time until the second power supply is started without using a circuit or a program for measuring the power supply voltage.

  In the first embodiment, the control unit 403, which is an example of a notification unit, notifies the user of the time for stopping the power supply to the fixing belt unit 200. By performing the standby after notifying the standby time, the user can know the reason for the standby state of the image forming apparatus 100 and perform unnecessary measures such as turning off the power and opening the apparatus main body. Can be avoided.

  In the first embodiment, when the temperature of the heater in the fixing device is controlled to the target temperature, the reason why the heater temperature cannot be reached to the target temperature is the main factor or an external factor (for example, the input AC voltage is unstable). It is possible to determine whether the device is below the rated input voltage range determined by the device. Similarly, when the heater temperature becomes higher than the target temperature within a certain period of time, the main factor or external factor (for example, the input voltage range is unstable and the device is over the rated input voltage range determined by the device) Case) is also detectable.

  In the first embodiment, the fluctuation of the power supply voltage is detected by calculating the temperature increase acceleration α of the temperature transition of the fixing belt 201. By calculating the temperature rise acceleration at the time of the first power supply, the fluctuation of the input AC voltage is judged and the cause of the abnormality at the time of the first power supply is determined. Thereby, it is possible to reduce unnecessary error processing from being executed and to appropriately set a waiting time until a retry. By appropriately setting the waiting time, unnecessary errors due to external factors can be reduced, and printing with satisfactory fixing performance can be performed. It is possible to perform printing satisfying the stable fixing property in the fixing device 110.

<Other embodiments>
The heating device of the present invention is not limited to the specific configuration described in the first and second embodiments. Another embodiment in which a part or all of the configuration of the first and second embodiments is replaced with an equivalent member is also possible. The first embodiment does not limit the invention according to the claims, and all combinations of features described in the first embodiment are not necessarily essential to the configuration of the invention.

  For example, in the first embodiment, the embodiment of the fixing device 110 in which the pressure roller 208 is pressed against the fixing belt 201 has been described. However, the present invention may be implemented in a roller fixing device in which a pressure roller is pressed against a fixing roller, a belt fixing device in which a pressure belt is pressed against a fixing belt, or a roller / belt fixing device in which a pressure belt is pressed against a fixing roller. Good. As the fixing device, a conventionally known fixing device can be adopted.

  The temperature of the fixing belt may be controlled so that the heater maintains a predetermined temperature using a temperature detection element such as a thermistor that directly detects the temperature of the heater in the fixing device.

  The heating device for heating the sheet is not limited to the fixing device. You may implement this invention in a sheet drying apparatus, a sheet heating apparatus, and a decurling apparatus. Any apparatus that heats a sheet to a predetermined temperature and causes underheating / overheating due to a power source factor can be used. The heating means is not limited to a ceramic heater. A halogen lamp heater, a lamp heater, a resistance heating device, a sheet heater, an IH heating device, or a heat pipe heating device may be substituted.

  The image forming apparatus can be implemented as, for example, a copying machine, a printer, a facsimile machine, or a complex machine thereof. The image forming apparatus is not limited to executing an electrophotographic process. Any of monochrome images, full-color images, line drawings, and photographs may be formed.

  In the first embodiment, the case where the input AC voltage is supplied to the heater as it is to perform the ON / OFF control has been described. However, the present invention can also be implemented when a DC constant voltage is generated from a varying AC current and the heater is heated by ON / OFF control of the generated DC voltage. In the case where the heater is heated by the DC constant voltage ON / OFF control, this embodiment can be implemented even when the duty ratio is other than 100%. Even when the AC voltage is converted to the DC voltage, if the input voltage does not reach the desired voltage, the total power will be insufficient, causing the problem that the heater cannot be raised to the desired temperature. Can do.

  In the first embodiment, “temperature rise acceleration, which is the rate of change in temperature rise per unit time” is used as a control parameter. However, the same determination as in the first embodiment is made using parameters such as “temperature increase rate that is a temperature increase amount per unit time”, “time until reaching a predetermined temperature”, “temperature increase amount for a predetermined time”, and the like. It is also possible to perform. However, in the latter case, since only the change between two points is known, it is difficult to determine whether the trend is upward or downward. If the temperature increase acceleration α exceeds 0, the temperature tends to increase and sometime reaches the rated voltage. For this reason, when “temperature rise acceleration” is used as a control parameter, there is an advantage that only one retry is required by accurately retrying when reaching the rated voltage.

  In the first embodiment, the fluctuation of the power supply voltage is detected by calculating the temperature rise acceleration α of the temperature transition of the fixing belt 201. However, by providing a voltage detection unit that directly detects fluctuations in the power supply voltage during heating of the heater, it is possible to appropriately provide a standby time until the power supply voltage is stabilized as in the first embodiment. That is, the control unit 403 supplies power to the fixing belt unit 200 after a lapse of time according to “detected power supply voltage fluctuation”, which is an example of a power supply state, after stopping power supply to the fixing belt unit 200. Is also possible.

1: exposure device, 2: photosensitive drum, 3: charging roller, 4: developing device, 5: drum cleaning device, 6: cassette, 7: pickup roller, 8: separation unit, 11: registration roller, 12: transfer roller, 14: discharge roller, 100: image forming device, 110: fixing device (heating device), 120: image forming unit, 130: paper feeding unit, 140: discharge unit, 200: fixing belt unit (heating means), 201: fixing Belt: 202: Belt guide, 205: Stay, 208: Pressure roller, 209, 210, 211: Thermistor (detection means), 212a, 212b: Fixing flange, 217a, 217b: Pressure spring, 220: Motor, 400: Power supply unit (power supply voltage), 401: engine control unit, 403: control unit (determination means, control means, notification means), 404: temperature control Department, 411: CPU, M: seat

Claims (10)

Heating means for heating the sheet;
Determining means for determining a state of temperature change during heating of the heating means;
Control means for supplying power again to the heating means after stopping the power supply to the heating means for a time according to the state of the temperature change determined by the determination means,
A heating device characterized by that. A detecting means for detecting the temperature of the heating means;
The determination means determines the rate of temperature increase detected by the detection means,
The control means stops power supply to the heating means for a time corresponding to the rate of increase;
The heating apparatus according to claim 1. The control means stops power supply to the heating means for a time corresponding to the increase rate when the temperature detected by the detection means does not reach the target temperature within a predetermined time.
The heating apparatus according to claim 2. The time for stopping the power supply to the heating means is set shorter as the temperature increase rate determined by the determination means is higher.
The heating apparatus according to claim 3. The control means prohibits power supply when the temperature increase rate is zero,
The heating apparatus according to claim 4. A notification means for notifying a time to stop power supply to the heating means;
The heating apparatus according to any one of claims 1 to 5, wherein Heating means for heating the sheet;
Control means for supplying power to the heating means after elapse of time according to the state of the power supply after stopping the power supply to the heating means,
A heating device characterized by that. An image forming unit that forms a toner image and transfers the toner image to a sheet;
A heating device according to any one of claims 1 to 7, wherein the sheet having the toner image transferred thereon by the image forming unit is heated.
An image forming apparatus. A method of controlling a heating device provided with a heating means for heating a sheet,
A determination step of determining a state of temperature change during heating of the heating means;
A power supply step of supplying power again to the heating means after stopping the power supply to the heating means for a time according to the state of the temperature change determined in the determination step,
A method for controlling a heating device. A method of controlling a heating device provided with a heating means for heating a sheet,
After stopping the power supply to the heating means, power is supplied to the heating means after elapse of time according to the state of the power source,
A method for controlling a heating device.

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