JP2012063644A - Fixing controller, image forming device and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide fixing control technology capable of suppressing wasteful power consumption by more accurately judging the occurrence of a chemical attack while reducing flicker.SOLUTION: A central color temperature detection part 612 detects a color temperature of a central part of a halogen heater. An end part color temperature detection part 613 detects a color temperature of an end part of the halogen heater. A halogen gas concentration detection part 614 detects a halogen gas concentration at the end part using correlation between the color temperature of the central part and the color temperature of the end part. A halogen cycle lighting control part 615 determines whether a chemical attack occurs or not using the color temperature at the end part and the halogen gas concentration at the end part, and when the determination result is positive, turns on a halogen lamp so that the halogen gas concentration in the halogen heater is made uniform.

Description

  The present invention relates to a fixing control device, an image forming apparatus, and a program.

  In an electrophotographic image forming apparatus, a toner image in which an electrostatic latent image is visualized by toner is transferred to a printing paper, and the toner image is fixed on the printing paper by a fixing heater, thereby performing printing. As such a fixing heater, a halogen heater is often used. In order to control such a fixing heater, control for reducing flickering of a halogen lamp used for the halogen heater (referred to as flicker) is required. Conventionally, as a control method for controlling the fixing heater (referred to as a fixing control method), for example, control methods such as half-wave control and half-wave phase control are already known. In recent years, a technique for suppressing a decrease in the lifetime of the halogen heater has been developed. For example, a technique has been developed for controlling the temperature of a halogen lamp by detecting the color temperature of a tungsten filament used in the halogen lamp and turning on the halogen lamp based on the color temperature. In particular, in the technique of Patent Document 1, the shortest lighting time can be set according to the current supplied to the halogen lamp and the mass of the coil. According to such a technique, it is possible to suppress a decrease in the life of the fixing heater due to occurrence of chemical attack without entering the halogen cycle while reducing flicker.

  The halogen cycle is as follows. A tungsten filament used for a halogen lamp becomes incandescent when a current is supplied and energized, the temperature becomes high, and tungsten (W) is sublimated. The sublimated W moves to the inner wall surface region of the arc tube of the halogen lamp, which is a relatively low temperature portion, and combines with halogen (X) to form tungsten halide (WX2). Since the vapor pressure of WX2 is relatively high, it returns to the vicinity of the tungsten filament part again in the gas state. When heated near 1,400 ° C near the tungsten filament, WX2 separates into X and W, W returns to the tungsten filament, and free X repeats the same reaction again. This is the halogen cycle.

  In contrast, chemical attack is as follows. Before the tungsten filament reaches a high temperature (temperature at which tungsten is sublimated), the activated halogen reacts directly with the tungsten on the tungsten filament to form tungsten halide (WX2). This is a chemical attack. Tungsten filaments become uneven due to corrosion. This phenomenon does not occur if the concentration of the halogen gas (halogen gas concentration) is low or if the halogen is completely used for the halogen cycle at the normal temperature position.

  In the conventional technique, the color temperature of the tungsten filament is detected, it is determined whether or not a chemical attack has occurred, and the lighting of the halogen heater is controlled according to the detected color temperature. However, in practice, the concentration of the halogen gas sealed in the halogen heater is also a factor that causes chemical attack. Even if the color temperature reaches the level of occurrence of chemical attack, the halogen gas concentration is below a certain value. If so, no chemical attack will occur. That is, in the conventional technology, it may be erroneously determined that a chemical attack has occurred, and power is wasted to the fixing heater in order to increase the color temperature even though no chemical attack has occurred. As a result, there is a risk that power is wasted.

The present invention has been made in view of the above, and it is possible to more accurately determine the occurrence of a chemical attack while reducing flicker and to suppress wasteful power consumption, an image forming apparatus, and an image forming apparatus. The purpose is to provide a program.

  In order to solve the above-described problems and achieve the object, the present invention provides an image forming apparatus for fixing an image on a print medium by heat of a halogen heater using a halogen lamp in which a halogen gas is sealed. A fixing control device for controlling lighting of the halogen heater, the color temperature detecting means for detecting the color temperature of the central portion and the end portion of the halogen heater, the color temperature of the central portion and the color of the end portion, respectively. Using the temperature correlation, the concentration detection means for detecting the first halogen gas concentration which is the concentration of the halogen gas at the end, the color temperature of the end and the first halogen gas concentration, A judgment means for judging whether or not a chemical attack has occurred, and a halogen gas in the halogen heater when the judgment means judges that a chemical attack has occurred. And a controlling means for turning on the halogen lamp so as to equalize the second halogen gas concentration is the concentration.

  The present invention also provides a program for controlling lighting of the halogen heater in an image forming apparatus that fixes an image on a print medium by heat of the halogen heater using a halogen lamp in which a halogen gas is sealed. A computer used in the fixing control device that uses the color temperature detection means for detecting the color temperature of the central portion and the end portion of the halogen heater, and the correlation between the color temperature of the central portion and the color temperature of the end portion. Thus, a chemical attack is generated by using the concentration detecting means for detecting the first halogen gas concentration which is the concentration of the halogen gas at the end portion, the color temperature at the end portion and the halogen gas concentration at the end portion. A halogen gas in the halogen heater when the determination unit determines that a chemical attack has occurred, To function as a control means for lighting the halogen lamp so as to equalize the second halogen gas concentration is the concentration.

  According to the present invention, it is possible to more accurately determine the occurrence of a chemical attack while reducing flicker, thereby suppressing wasteful power consumption.

FIG. 1 is a diagram illustrating an outline of a configuration of an image forming apparatus according to an embodiment. FIG. 2 is a diagram illustrating a configuration related to the fixing unit 20. FIG. 3 is a diagram illustrating the function of the fixing heater control unit 610. FIG. 4 is a flowchart showing a processing procedure for detecting the color temperature and halogen gas concentration of the tungsten filament of the halogen heater 20A. FIG. 5 is a flowchart showing a processing procedure for detecting the color temperature of the central portion of the halogen heater 20A in step S1 of FIG. FIG. 6 is a flowchart showing a procedure of processing for detecting the halogen gas concentration at the end of the halogen heater 20A in step S3 of FIG. FIG. 7 is a flowchart showing a procedure of processing for performing chemical attack countermeasure lighting control using the color temperature detected in step S2 of FIG. 4 and the halogen gas concentration detected in step S3. FIG. 8 is a flowchart showing a processing procedure for determining whether or not a chemical attack has occurred in step S4 of FIG. FIG. 9 is a flowchart showing a procedure of processing for determining whether or not the chemical attack countermeasure lighting control is terminated in step S7 of FIG. FIG. 10 is a flowchart illustrating a procedure of a process for determining whether or not the end of the chemical attack countermeasure lighting control according to the modification is appropriate. FIG. 11 is a flowchart showing a procedure of processing for determining whether or not the end of the chemical attack countermeasure lighting control according to one modified example.

  Exemplary embodiments of a fixing control device, an image forming apparatus, and a program according to the present invention will be explained below in detail with reference to the accompanying drawings.

  FIG. 1 is a diagram illustrating an outline of the configuration of the image forming apparatus according to the present embodiment. In the present embodiment, an electrophotographic image forming apparatus will be described as an example. Since the configuration of such an image forming apparatus is already known, only the outline will be described here. The image forming apparatus includes a reading optical system unit 21, a writing optical system unit 27, a fixing unit 20, a control unit, and a power supply unit (not shown), and realizes a copy function and a printing function. The control unit controls the entire image forming apparatus. The power supply unit converts an alternating current supplied from an AC (Alternating Current) power source into a direct current, and supplies or stops the supply of a direct current force to each unit under the control of the control unit. The reading optical system unit 21 includes a light source 22 for irradiating light on a document, a mirror group 24 for guiding reflected light to a condenser lens 23, an image reading element 25 for reading the collected reflected light, and a light source 22. The fan 26 is configured to release the generated heat to the outside. The writing optical system unit 27 reflects light from a light emitting light source (not shown) by a polygon mirror 28 that is timed, condensed by a lens group 29, and reflected by a mirror 30 in a predetermined direction to be charged. An electrostatic latent image that matches the read image is formed by being guided to the surface of the photosensitive drum 31 that is already charged by the charger 32. This electrostatic latent image is visualized by toner carried by the developing roller 33. The fixing unit 20 includes a fixing roller 6 having a built-in heat source of a halogen heater using a halogen lamp 5 in which a halogen gas is sealed, and a pressure roller 7 in pressure contact.

  Printing paper is stored in the paper feed cassette 34, and the printing paper is fed to a predetermined position of the photosensitive drum 31 by the paper feeding roller 35, and the timing of rotation (in the direction of the arrow) of the photosensitive drum 31 is reached. The toner image which is moved together and visualized by the action of the transfer charger 36 is transferred onto the printing paper. Thereafter, the charge applied to the printing paper by the separation charger 37 is discharged, the printing paper is separated from the photosensitive drum 31, the toner image is heat-fixed on the printing paper by the fixing unit 20, and is stored in the storage stacker 40 by the discharge roller 39. Sent out. Further, the toner remaining on the surface of the photosensitive drum 31 after the toner image is transferred to the printing paper is removed by the cleaning unit 38.

  Here, the configuration related to the fixing unit 20 will be described in detail with reference to FIG. The fixing unit 20 includes the above-described halogen heater 20A, thermistor 20B, and two illuminance sensors 20C and 20D. The power supply unit 50 includes a filter 51, an electromagnetic relay (RA) 52, a zero cross detection circuit 53, a rectifier circuit 54, and a DDC circuit 55. The electromagnetic relay 52 of the power supply unit 50 and the halogen heater 20 </ b> A are connected via a triac (TRI) 70. The halogen heater 20 </ b> A is a heat source in which the halogen lamp 5 described above is used, and is built in the fixing roller 6. The thermistor 20B detects the temperature of the fixing roller 6 heated by the halogen heater 20A. The illuminance sensors 20C and 20D are provided at the center and the end of the halogen heater 20A, respectively, and measure the illuminance.

  The zero cross detection circuit 53 detects the passage of the AC voltage at the zero point (zero cross point) when the AC power source is turned on / off by the power switch 80. When the power switch 80 is turned on, the filter 51 removes noise from the current supplied from the AC power supply and supplies it to the rectifier circuit 54 and the electromagnetic relay 52. The rectifying circuit 54 rectifies the alternating current supplied from the filter 51 and supplies the rectified current to the DDC circuit 55. The DDC circuit 55 converts the alternating current supplied from the rectifier circuit 54 into a direct current and supplies it to the control unit 60. The electromagnetic relay 52 supplies the alternating current supplied from the filter 51 to the TRI 70 under the control of a CPU 61 included in the control unit 60 described later. The TRI 70 is turned on or off under the control of the CPU 61 to supply or stop the supply of alternating current to the halogen heater 20A.

  The control unit 60 includes a CPU (Central Processing Unit) 61 that controls the entire image forming apparatus, a main storage unit such as a ROM (Read Only Memory) and a RAM (Random Access Memory) that stores various data and various programs, and various types of data. And an auxiliary storage unit such as an HDD (Hard Disk Drive) for storing data and various programs. The CPU 61 executes the main storage unit, the auxiliary storage unit, and various stored programs, thereby controlling the entire image forming apparatus and realizing various functions in the image forming apparatus. Specifically, the CPU 61 realizes the function of the fixing heater control unit 610 that performs fixing control in the fixing unit 20.

  Here, the function of the fixing heater control unit 610 will be described with reference to FIG. The fixing heater control unit 610 controls the halogen heater 20A by selecting either half wave control or half wave phase control as a fixing control method for controlling the halogen heater 20A. The halogen cycle control unit 611. The halogen cycle control unit 611 controls lighting (referred to as lighting control) of the halogen lamp 5 used in the halogen heater 20A in the fixing control, and includes a central color temperature detection unit 612, an end color temperature detection unit 613, and a halogen. A gas concentration detection unit 614 and a halogen cycle lighting control unit 615 are provided. The entities of these units are generated on a main storage unit such as a RAM when the CPU 61 executes various programs.

  The central color temperature detection unit 612 includes an illuminance sensor detection unit 616, a color temperature conversion unit 617, and a storage unit 618. The illuminance sensor detection unit 616 detects the illuminance measured by the illuminance sensor 20C provided at the center of the halogen heater 20A. The storage unit 618 is a storage area on an auxiliary storage unit such as an HDD, and stores first correlation data indicating the correlation between illuminance and color temperature. The color temperature is a scale (unit) for expressing the color of light emitted from a light source emitting a certain color as a quantitative numerical value. Correlation is a relationship in which the other changes in response to one change. The color temperature conversion unit 617 obtains a color temperature corresponding to the illuminance detected by the illuminance sensor detection unit 616 using the first correlation data stored in the storage unit 618. Note that the color temperature of the tungsten filament used in the halogen heater 20A is slow to follow and cannot be directly detected by fixing control that changes in units of 10 ms. For this reason, the color temperature is obtained using the illuminance measured by the illuminance sensor 20C. As described above, the central color temperature detection unit 612 detects the color temperature of the central part of the halogen heater 20A.

  The end color temperature detection unit 613 includes an illuminance sensor detection unit 619, a color temperature conversion unit 620, and a storage unit 621. The illuminance sensor detection unit 619 detects the illuminance measured by the illuminance sensor 20D provided at the end of the halogen heater 20A. The storage unit 621 is the same as the storage unit 618. The color temperature conversion unit 620 obtains a color temperature corresponding to the illuminance detected by the illuminance sensor detection unit 619 using the first correlation data stored in the storage unit 621. As described above, the end color temperature detection unit 613 detects the color temperature of the end of the halogen heater 20A.

  The halogen gas concentration detection unit 614 includes a color temperature-halogen gas concentration correlation data holding unit 622. The color temperature-halogen gas concentration correlation data holding unit 622 is a storage area on an auxiliary storage unit such as an HDD, for example, and the color temperature difference between the center and the end of the halogen heater 20A and the end of the halogen heater 20A. Second phase data indicating the correlation between the color temperature and the amount of halogen gas sealed in the halogen heater 20A and the halogen gas concentration is stored. The concentration of the halogen gas enclosed in the halogen heater 20A (halogen gas concentration) varies depending on the color temperature difference between the end and the center of the halogen heater 20A, and the concentration increases at a low temperature portion. is there. Further, since the color temperature and the halogen gas concentration, which are threshold values for the occurrence of chemical attack, differ for each halogen heater 20A, it is necessary to obtain the values in advance, and the central portion of the halogen heater 20A to be subjected to fixing control It is obtained by measuring in advance the change in each color temperature with the end. Then, utilizing the properties of the halogen gas, the difference in color temperature between the central portion and the end portion of the halogen heater 20A, the color temperature of the end portion of the halogen heater 20A, the amount of halogen gas sealed in the halogen heater 20A, and the halogen The correlation between the gas concentrations is grasped in advance, and the second correlation data indicating this correlation is stored in the color temperature-halogen gas concentration correlation data holding unit 622.

  The halogen gas concentration detection unit 614 calculates the difference in color temperature between the central portion and the end portion of the halogen heater 20A using the color temperature obtained by the color temperature conversion unit 617 and the color temperature obtained by the color temperature conversion unit 620. The concentration of the halogen gas at the end of the halogen heater 20A is detected by obtaining the halogen gas concentration with reference to the second correlation data stored in the color temperature-halogen gas concentration correlation data holding unit 622.

  The halogen cycle lighting control unit 615 determines whether or not a chemical attack has occurred using the halogen gas concentration detected by the halogen gas concentration detection unit 614 and the color temperature detected by the end color temperature detection unit 613. At the same time, it is determined whether or not the halogen cycle has been started, and lighting control of the halogen heater 20A is performed according to the determination result. This lighting control is to control the electromagnetic relay 52 and the TRI 70 described above to control the supply of alternating current to the halogen heater 20A and the stop of the supply, and the temperature of the fixing roller 6 detected by the thermistor 20B. However, the color temperature of the halogen heater 20A is controlled by turning on or off the halogen lamp 5 so as to be stabilized at a preset target temperature.

The criteria for chemical attack are as follows. As described above, the color temperature and the halogen gas concentration, which are threshold values for the occurrence of chemical attack, differ for each halogen heater 20A. For example, when the halogen gas concentration threshold (referred to as the concentration threshold) is set to 10 ⁻⁴ atm and the color temperature at the end (referred to as the color temperature threshold) is set to 2000 K, the halogen cycle lighting control unit 615 displays the halogen gas concentration. When the halogen gas concentration detected by the detection unit 614 is 10 ⁻⁴ atm or more and when the color temperature detected by the end color temperature detection unit 613 is 2000 K or less, it is determined that a chemical attack has occurred. In this case, the halogen cycle lighting control unit 615 turns on the halogen lamp 5 to set the color temperature of the halogen heater 20A so as to enter the halogen cycle, that is, to make the concentration of the halogen gas in the halogen heater 20A uniform. Lighting control to raise (referred to as chemical attack countermeasure lighting control).

In addition, the halogen cycle lighting control unit 615 determines that the halogen cycle has been entered when the halogen gas concentration detected by the halogen gas concentration detection unit 614 is less than 10 ⁻⁴ atm during the chemical attack countermeasure lighting control. Then, in order to end the chemical attack countermeasure lighting control, the halogen lamp 5 is turned off, and the lighting control similar to that in the case where no chemical attack occurs is performed.

  Next, a processing procedure performed by the image forming apparatus according to the present embodiment will be described. First, the procedure of processing for detecting the color temperature and halogen gas concentration of the tungsten filament of the halogen heater 20A will be described with reference to FIG. The image forming apparatus detects the color temperature of the central portion of the halogen heater 20A by the function of the central color temperature detection unit 612 (step S1). Further, the image forming apparatus detects the color temperature of the end of the halogen heater 20A by the function of the end color temperature detection unit 613 (step S2). Next, the image forming apparatus uses the color temperature at the center of the halogen heater 20A detected at step S1 and the color temperature at the end of the halogen heater 20A detected at step S2 by the function of the halogen gas concentration detection unit 614. Then, the halogen gas concentration at the end of the halogen heater 20A is detected (step S3). Note that the image forming apparatus performs the processing of steps S1 to S3 periodically or at an arbitrary timing.

  Here, the procedure of the process of detecting the color temperature of the central portion of the halogen heater 20A in step S1 will be described with reference to FIG. When the illuminance is measured by the illuminance sensor 20C (step S10: YES), the image forming apparatus refers to the first correlation data stored in the storage unit 618 by the function of the central color temperature detection unit 612. Is obtained (step S11). If the determination result of step S10 is negative, the process returns to step S10. Note that the processing procedure for detecting the color temperature at the end of the halogen heater 20A in step S2 is the same as that in FIG. In step S10, when the illuminance is measured by the illuminance sensor 20D in step S10 (step S10: YES), in step S11, the first color information stored in the storage unit 621 is stored in the storage unit 621 by the function of the edge color temperature detection unit 613. The color temperature corresponding to the illuminance is obtained with reference to the correlation data.

  Next, the processing procedure for detecting the halogen gas concentration at the end of the halogen heater 20A in step S3 will be described with reference to FIG. The image forming apparatus uses the function of the halogen gas concentration detection unit 614 to use the color temperature at the center of the halogen heater 20A detected at step S1 and the color temperature at the end of the halogen heater 20A detected at step S2. A difference in color temperature between the central portion and the end portion is calculated (step S20), and the color temperature difference (Kdif) is referred to by referring to the second correlation data stored in the color temperature-halogen gas concentration correlation data holding unit 622. The halogen gas concentration (Dend) at the end of the halogen heater 20A is obtained by obtaining the halogen gas concentration (Dend) corresponding to the color temperature (Kend) at the end and the amount of the halogen gas sealed in the halogen heater 20A. It detects (step S21).

  Next, a procedure of processing for performing chemical attack countermeasure lighting control using the color temperature detected in step S2 and the halogen gas concentration detected in step S3 will be described with reference to FIG. The image forming apparatus determines whether or not a chemical attack has occurred by the function of the halogen cycle lighting control unit 615 (step S4). If it is determined that a chemical attack has occurred (step S5: YES), In order to enter the halogen cycle, chemical attack countermeasure lighting control is performed (step S6). Thereafter, the image forming apparatus determines whether or not to end the chemical attack countermeasure lighting control (step S7). If it is determined to end (step S8), the image forming apparatus ends the chemical attack countermeasure lighting control (step S9). The lighting control is performed in the same manner as when no chemical attack has occurred. If the determination result in step S5 is negative, the process returns to step S4. If the determination result in step S8 is negative, the process returns to step S7.

  Here, the procedure of the process for determining whether or not a chemical attack has occurred in step S4 will be described with reference to FIG. The image forming apparatus determines whether the color temperature (Kend) detected in step S2 is smaller than the color temperature threshold (Kthre) by the function of the halogen cycle lighting control unit 615 (step S30). If the determination result is negative (step S30: NO), the image forming apparatus determines that no chemical attack has occurred, returns to step S30, and if the determination result is positive (step S30). : YES), it is determined whether or not the halogen gas concentration (Dend) detected in step S3 is larger than the concentration threshold (Dthre) (step S31). If the determination result is negative (step S31: NO), the image forming apparatus determines that no chemical attack has occurred, returns to step S31, and if the determination result is positive (step S31). : YES), it is determined that a chemical attack has occurred (step S32). In this case, the determination result of step S5 of FIG. 7 is affirmative, and the process proceeds to step S6.

  In step S6, the image forming apparatus performs a chemical attack countermeasure lighting control for turning on the halogen lamp 5 and increasing the color temperature of the halogen heater 20A so as to enter the halogen cycle. Thereafter, the image forming apparatus determines whether or not to end the chemical attack countermeasure lighting control (step S7).

  Here, the processing procedure for determining whether or not the end of the chemical attack countermeasure lighting control in step S7 will be described with reference to FIG. As described above, the image forming apparatus performs the processing of steps S1 to S3 periodically or at an arbitrary timing. Therefore, when the image forming apparatus newly detects the halogen gas concentration in step S3 while performing the chemical attack countermeasure lighting control, it is determined whether or not the halogen gas concentration (Dend) is smaller than the concentration threshold (Dthre). Judgment is made (step S40). If the determination result is negative (step S40: NO), the image forming apparatus determines that the chemical attack countermeasure lighting control is not terminated because it has not entered the halogen cycle, and returns to step S40. Is affirmative (step S40: YES), it is determined that the halogen cycle has been entered, and it is determined that the chemical attack countermeasure lighting control is to be terminated (step S41). In this case, the determination result of step S7 in FIG. 7 is affirmative, and the process proceeds to step S8.

  In step S8, the image forming apparatus turns off the halogen lamp 5, ends the chemical attack countermeasure lighting control, and performs lighting control similar to that in the case where no chemical attack has occurred.

  As described above, an illuminance sensor is provided not only at the end of the halogen heater 20A where chemical attack is significant but also at the center, and the illuminance measured at each of the end and center of the halogen heater 20A is used. The color temperature of each of the end portion and the center portion is detected. Due to the difference in color temperature, the concentration of the halogen gas sealed in the halogen heater 20A is biased. Therefore, by detecting the color temperature and the color temperature difference between the center and the end, the halogen gas concentration at the end is determined. The occurrence of a chemical attack can be determined more accurately based on the detected halogen gas concentration and end color temperature. Conventionally, since the occurrence of a chemical attack is determined using only the color temperature, there is a possibility that a halogen lamp used for the halogen heater is turned on unnecessarily and power is wasted due to an erroneous determination. On the other hand, in the present embodiment, the occurrence of a chemical attack is determined more accurately, and a lighting control is performed to turn on the halogen lamp 5 so as to enter the halogen cycle. The useless lighting of the halogen lamp 5 can be avoided. For this reason, wasteful power consumption can be suppressed while reducing flicker.

[Modification]
Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. Moreover, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment. Furthermore, constituent elements over different embodiments may be appropriately combined. Further, various modifications as exemplified below are possible.

  In the embodiment described above, various programs executed by the image forming apparatus may be stored on a computer connected to a network such as the Internet and provided by being downloaded via the network. The various programs are recorded in a computer-readable recording medium such as a CD-ROM, a flexible disk (FD), a CD-R, and a DVD (Digital Versatile Disk) in a file in an installable or executable format. The computer program product may be provided.

  In the above-described embodiment, the image forming apparatus realizes the copy function and the print function. However, in addition to this, the image forming apparatus may be a multifunction machine that further realizes a scanner function and a facsimile function. May be a copier that realizes the above, or a printer that realizes the print function.

  In the above-described embodiment, the storage unit 618 stores a calculation formula for obtaining the color temperature from the illuminance using the correlation between the illuminance and the color temperature, not the first correlation data indicating the correlation between the illuminance and the color temperature. The color temperature conversion unit 617 may calculate the color temperature corresponding to the illuminance detected by the illuminance sensor detection unit 616 using the calculation formula stored in the storage unit 618. The same applies to the storage unit 621 and the color temperature conversion unit 620.

  Further, the color temperature-halogen gas concentration correlation data holding unit 622 includes a difference in color temperature between the center and the end of the halogen heater 20A, a color temperature at the end of the halogen heater 20A, and a halogen enclosed in the halogen heater 20A. Instead of the second correlation data indicating the correlation between the amount of gas and the halogen gas concentration, this correlation is used to determine the difference in color temperature between the central portion and the end portion of the halogen heater 20A or the color temperature at the central portion and the end portion. The calculation formula for calculating the halogen gas concentration at the end using the color temperature as a variable is stored, and the halogen cycle lighting control unit 615 stores the calculation formula stored in the color temperature-halogen gas concentration correlation data holding unit 622. The halogen gas concentration at the end is calculated from the difference in color temperature between the center and end of the halogen heater 20A or the color temperature at the center and the color temperature at the end. There.

  In the above embodiment, the image forming apparatus performs the process shown in FIG. 9 in step S7 of FIG. 7, but the present invention is not limited to this. When the image forming apparatus performs the chemical attack countermeasure lighting control, the halogen gas concentration at the end of the halogen heater 20A becomes low. For this reason, the image forming apparatus predicts the timing at which the halogen gas concentration falls below the concentration threshold from the lower slope, predicts the timing at which the chemical attack countermeasure lighting control ends, and performs the chemical attack countermeasure lighting control at the predicted timing. The lighting control may be performed in the same manner as when no chemical attack has occurred. FIG. 10 is a flowchart showing a procedure of processing for determining whether or not the end of the chemical attack countermeasure lighting control according to the present modification. When the image forming apparatus newly detects the halogen gas concentration in step S3 (step S50), the function of the halogen cycle lighting control unit 615 starts from the time when the halogen gas concentration (Dend) is equal to or lower than the concentration threshold (Dthre). A time T for turning off the halogen lamp 5 is predicted (step S51). Then, the image forming apparatus measures the passage of time and determines whether or not the time T predicted in step S51 has been reached (step S52). When the determination result is negative (step S52: NO), the image forming apparatus determines not to end the chemical attack countermeasure lighting control, returns to step S52, and when the determination result is affirmative (step S52: YES), it is determined to end the chemical attack countermeasure lighting control (step S53). In this case, the determination result of step S7 in FIG. 7 is affirmative, and the process proceeds to step S8.

  As described above, the image forming apparatus predicts the turn-off timing of the halogen lamp 5 from the tendency of change in the halogen gas concentration during the chemical attack countermeasure lighting control, and the halogen lamp 5 at the predicted timing. By turning off, the halogen lamp 5 can be turned off early before the halogen gas concentration actually becomes smaller than the concentration threshold value, and overshooting can be prevented. For this reason, wasteful power consumption can be more effectively suppressed.

  In addition, in step S7 of FIG. 7, processing as shown in FIG. 11 may be performed. The image forming apparatus determines whether or not the color temperature of the end of the halogen heater 20A newly detected in step S2 is equal to or higher than the color temperature threshold by the function of the halogen cycle lighting control unit 615 (step S60). When the determination result is negative (step S60: NO), the image forming apparatus determines not to end the chemical attack countermeasure lighting control, returns to step S60, and when the determination result is affirmative (step S60). S60: YES), the fixing control method is changed to the half-wave control method, and the chemical attack countermeasure lighting control is performed (step S61). Then, the image forming apparatus determines whether or not the halogen gas concentration at the end of the halogen heater 20A newly detected in step S3 is equal to or lower than the concentration threshold value (step S62). If the determination result is negative (step S62: NO), the image forming apparatus determines not to end the chemical attack countermeasure lighting control, returns to step S62, and if the determination result is affirmative (step S62: YES), it is determined that the chemical attack countermeasure lighting control is to be ended (step S63). In this case, the determination result of step S7 in FIG. 7 is affirmative, and the process proceeds to step S8.

  As described above, during the chemical attack countermeasure lighting control, the fixing control is performed until the halogen gas concentration reaches the concentration threshold after the color temperature at the end of the halogen heater 20A exceeds the color threshold. By using the half-wave control method, it is possible to control wasteful power consumption while maintaining a color temperature that is equal to or higher than the color temperature threshold, and to control temperature ripple and reduce flicker. .

  In the embodiment described above, the illuminance sensor 20D is provided at the end of the halogen heater 20A. However, the illuminance sensor 20D may be provided at both ends of the halogen heater 20A, or the illuminance sensor may be provided at either end. 20D may be provided.

5 Halogen lamp 6 Fixing roller 7 Pressure roller 20 Fixing unit 20A Halogen heater 20B Thermistor 20C, 20D Illuminance sensor 50 Power supply unit 51 Filter 52 Electromagnetic relay 53 Zero cross detection circuit 54 Rectifier circuit 55 DDC circuit 60 Control unit 61 CPU
610 Fixing heater control unit 611 Halogen cycle control unit 612 Central color temperature detection unit 613 End color temperature detection unit 614 Halogen gas concentration detection unit 615 Halogen cycle lighting control unit 616 Illuminance sensor detection unit 617 Color temperature conversion unit 618 Storage unit 619 Illuminance Sensor detection unit 620 Color temperature conversion unit 621 Storage unit 622 Halogen gas concentration correlation data holding unit

JP-A-8-202200

Claims (10)

In an image forming apparatus for fixing an image on a print medium by heat of a halogen heater using a halogen lamp in which a halogen gas is enclosed, a fixing control device for controlling lighting of the halogen heater,
Color temperature detection means for detecting the color temperature at the center and end of the halogen heater,
A concentration detecting means for detecting a first halogen gas concentration which is a concentration of the halogen gas at the end portion using a correlation between the color temperature of the central portion and the color temperature of the end portion;
Determining means for determining whether or not a chemical attack has occurred using the color temperature of the end and the first halogen gas concentration;
Control means for turning on the halogen lamp so as to make the second halogen gas concentration equal to the concentration of the halogen gas in the halogen heater when the determination means determines that a chemical attack has occurred. A fixing control device. The determination means determines that a chemical attack has occurred when the color temperature of the end portion is lower than a first threshold and when the first halogen gas concentration is higher than a second threshold. Item 4. The fixing control device according to Item 1. When the determination means determines that a chemical attack has occurred, the control means turns on the halogen lamp so as to make the second halogen gas concentration uniform, and then the first halogen gas concentration. 3. The fixing control device according to claim 1, wherein the halogen lamp is extinguished when the value becomes equal to or less than the second threshold value. 4. When the determination means determines that a chemical attack has occurred, the control means turns on the halogen lamp to make the second halogen gas concentration uniform, and then changes the halogen gas concentration. 3. The fixing control according to claim 1, wherein a timing at which the first halogen gas concentration becomes equal to or lower than the second threshold is predicted based on the tendency, and the halogen lamp is turned off at the timing. apparatus. When the determination means determines that a chemical attack has occurred, the control means turns on the halogen lamp to make the second halogen gas concentration uniform, and then the color temperature of the end portion is changed. 3. The lighting of the halogen lamp is controlled by half-wave control until the halogen gas concentration at the end becomes equal to or lower than the second threshold when the threshold is equal to or higher than the first threshold. The fixing control device according to 1. The difference between the color temperature of the central portion and the color temperature of the end portion, the color temperature of the end portion, the amount of halogen gas sealed in the halogen heater, and the concentration of the halogen gas, the second halogen gas Storage means for storing correlation data indicating the correlation of concentration;
The concentration detection means detects the first halogen gas concentration by obtaining the first halogen gas concentration using the color temperature of the central portion, the color temperature of the end portion, and the correlation data. The fixing control device according to claim 1, wherein The difference between the color temperature of the central portion and the color temperature of the end portion or the color temperature of the central portion, the color temperature of the end portion, the amount of halogen gas sealed in the halogen heater, and the concentration of the halogen gas. Based on the correlation of the second halogen gas concentration, the first halogen gas concentration is calculated using the difference in color temperature or the color temperature of the central portion and the color temperature of the end portion as variables. It further comprises storage means for storing the calculation formula,
The concentration detection means detects the first halogen gas concentration by calculating the first halogen gas concentration using the color temperature of the central portion, the color temperature of the end portion, and the calculation formula. The fixing control apparatus according to claim 1, wherein the fixing control apparatus includes: The color temperature detecting means obtains the color temperature of the central portion by using the correlation between the illuminance and the color temperature measured by the first illuminance sensor provided in the central portion of the halogen heater, thereby obtaining the color of the central portion. By detecting the temperature and obtaining the color temperature of the central portion by using the correlation between the illuminance and the color temperature measured by the second illuminance sensor provided at the end of the halogen heater, the color temperature of the end is determined. The fixing control device according to claim 1, wherein the fixing control device detects the fixing control device. An image forming apparatus comprising the fixing control device according to claim 1. In an image forming apparatus for fixing an image on a print medium by heat of a halogen heater using a halogen lamp in which a halogen gas is enclosed, a computer used in a fixing control device that controls lighting of the halogen heater,
Color temperature detection means for detecting the color temperature at the center and end of the halogen heater,
A concentration detecting means for detecting a first halogen gas concentration which is a concentration of the halogen gas at the end portion using a correlation between the color temperature of the central portion and the color temperature of the end portion;
Judgment means for judging whether or not a chemical attack has occurred using the color temperature of the end and the halogen gas concentration of the end;
In order to function as a control means for lighting the halogen lamp so as to make the second halogen gas concentration equal to the halogen gas concentration in the halogen heater when the determination means determines that a chemical attack has occurred. Program.

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