KR20080032475A - Image forming device and method of the driving - Google Patents

Abstract

An image forming device and a driving method thereof are provided to prevent the heating of a fixing unit dually by the control of a control unit and hardware control when the surface of the fixing unit is heated and block the heating of the heating lamp of the fixing unit previously by initializing the control unit when the control unit is abnormally operated, thereby preventing the damage and fire of the internal parts of the fixing unit fundamentally. A temperature sensing unit(150) has a resistance value varied according to a change of the temperature of a fixing unit(120). A temperature comparison unit(180) outputs a comparison signal according to the difference between the phases of a temperature detection signal, formed on the basis of the resistance value of the temperature sensing unit, and a preset reference signal. A reset circuit unit(170) initializes a control unit in response to the comparison signal.

Description

Image forming apparatus and driving method thereof IMAGE FORMING DEVICE AND METHOD OF THE DRIVING

1 is a block diagram schematically illustrating a general image forming apparatus.

2 is a block diagram schematically illustrating an image forming apparatus according to an embodiment of the present invention.

FIG. 3 is a circuit diagram illustrating a specific embodiment of the fuser driver shown in FIG. 2.

FIG. 4 is a circuit diagram illustrating a specific embodiment of the temperature comparison unit and the reset circuit unit shown in FIG. 2.

5 is a diagram illustrating normal reset timing of the image forming apparatus shown in FIG. 2.

FIG. 6 is a diagram illustrating abnormal reset timing of the image forming apparatus shown in FIG. 2.

* Description of the symbols for the main parts of the drawings *

100: image forming apparatus 110: control unit

120: fuser 130: power supply

140: fuser drive unit 150: temperature sensing unit

160: protection circuit section 170: reset circuit section

180: temperature comparison unit

The present invention relates to an image forming apparatus and a driving method thereof, and more particularly, to an image forming apparatus which initializes the control unit and prevents a malfunction of the fixing unit when the control unit performing temperature control of the image forming apparatus is abnormally driven. It relates to a driving method.

The image forming apparatus means an apparatus which prints an image corresponding to the input image data onto a recording medium such as printing paper. Examples of such an image forming apparatus include a printer, a copier, a facsimile, and a multifunction printer incorporating these functions into one.

In general, the image forming apparatus needs a heat generating device for allowing a normal printing operation and a device for maintaining the heat generating device at a constant temperature. In particular, in the case of a fuser for fusing the formed toner image onto the print paper using heat and pressure, the fuser controls the heating lamp inside the fuser to maintain the surface at a target temperature suitable for fixing in order to fix the toner image on the paper. Requires a control device

1 is a block diagram schematically illustrating a general image forming apparatus. In particular, FIG. 1 illustrates a fuser and a control device of the fuser, and other portions are omitted.

Referring to FIG. 1, a general image forming apparatus includes a control unit 10, a fixing unit 20, a power supply unit 30, a fixing unit driver 40, a temperature sensing unit 50, a protection circuit unit 60, and a reset circuit unit 70. ).

The controller 10 controls the overall driving of each unit of the image forming apparatus. In particular, the control unit 10 is, for example, PWM so that the surface temperature of the fixing unit 20 is formed to the surface temperature of the preset temperature range in the driving mode of the fixing unit 20, for example, the setup mode, the standby mode and the printing mode. The surface temperature of the fixing unit 20 is controlled using a control method or the like.

Although not shown, the fixing unit 20 includes a heating lamp for forming the surface temperature of the fixing unit 20 at a high temperature in order to fuse the image formed on the printing medium to the printing medium.

The power supply unit 30 is formed of a switching mode power supply (SMPS), and rectifies and smoothes AC power input from the outside, or controls its potential to adjust the power supply voltage of each part of the image forming apparatus. Supply.

The fuser driver 40 is selectively activated under the control of the controller 10 to control the application of the power voltage output from the power supply unit 30 to the fuser 20.

The temperature sensing unit 50 detects the surface temperature of the fuser 20 to allow the controller 10 to control the surface temperature of the fuser 20 so that the temperature detection signal has a potential corresponding to the surface temperature of the fuser 20. Outputs To this end, the temperature sensing unit 50 includes a temperature sensor such as a thermistor whose resistance value varies according to the surface temperature of the fixing unit 20.

Although not shown, the protection circuit unit 60 may have a potential corresponding to a preset temperature such that the surface temperature of the fixing unit 20 is not formed at a temperature exceeding a preset temperature and a temperature detection signal output from the temperature sensing unit 50. By comparing the reference signal having a and applying the result to the control unit 10, the control unit 10 to control the driving of the fuser driver 40.

In addition, the protection circuit unit 60 includes a thermostat such as a thermostat for preventing the surface temperature of the fixing unit 20 from being formed above the heat resistance temperature in hardware.

The reset circuit unit 70 stabilizes the power supply voltage applied from the power supply unit 30 to the control unit 10 and stabilizes the clock signal in order to control the output timing of the synchronization signal required for the system, thereby stabilizing the system. The controller 10 is initialized by outputting a reset signal to the controller 10 during initial driving of the system to start the operation in the set state.

In the general image forming apparatus, when the surface temperature of the fixing unit 20 is formed to be higher than the heat resistance temperature, the above-described protection may occur due to deterioration of components such as the fixing unit, for example, bushing, or severe fire. In addition to the circuit unit 60, various protection circuits or internal components for protection are provided.

According to such a general image forming apparatus, the control unit 10 abnormally operates due to static electricity due to friction between the print medium and the fixing unit 20, such as printing paper passing through the fixing unit 20, or the temperature sensing port of the control unit 10. If the port is abnormally operated, it is possible to prevent the rise of the surface temperature of the fixing unit 20 by blocking the driving of the heating lamp of the fixing unit 10 with a thermostat such as, for example, a thermostat.

However, according to the general image forming apparatus, even when the control unit 10 operates abnormally, even if a temperature control device such as the thermostat operates normally, the heating lamp is instantaneously set in the case of the distance between the thermostat and the fixing unit 20 or the instantaneous fixing. Since the heating to a high temperature does not prevent the rise of the surface temperature of the fuser, it causes a problem of breakage of the internal parts of the image forming apparatus or the possibility of fire.

That is, when the control unit 10 malfunctions, there is a problem in that the temperature control of the fixing unit depending on the thermostat or the like cannot prevent the possibility of damage or fire of internal components.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and an object of the present invention is to provide an image forming apparatus which can prevent the surface temperature of the fixing unit from being overheated even when the controller is abnormally driven.

Another object of the present invention is to provide a method of driving the image forming apparatus.

In order to achieve the above object of the present invention, an image forming apparatus including a fixing unit according to an embodiment of the present invention, and a control unit for controlling the driving of the fixing unit includes a temperature sensing unit, a temperature comparing unit, and a reset circuit unit. . The temperature sensing unit has a resistance value that varies with temperature change of the fixing unit. The temperature comparison unit outputs a comparison signal according to a difference between the temperature detection signal formed on the basis of the resistance value of the temperature sensing unit and a preset reference signal. The reset circuit unit outputs a reset signal for initializing the controller in response to the comparison signal.

The temperature comparator may include a comparator circuit having a positive input terminal to which the temperature detection signal is input and a negative input terminal to which the reference signal is applied.

The reset circuit unit may include an integrated circuit having an input terminal to which the comparison signal is applied and an output terminal to which the reset signal is output.

Preferably, the temperature sensing unit includes a main thermistor for detecting the temperature of the fixing unit to form the temperature of the fixing unit at a target temperature, and a sub thermistor detecting the temperature of the fixing unit to prevent the fixing unit from overheating. The temperature detection signal may be formed based on a resistance value of the sub thermistor.

Here, the reference signal may be a potential corresponding to the heat resistance temperature of the fixing unit.

In order to achieve the above object of the present invention, a method of driving an image forming apparatus having a fixing unit according to an embodiment of the present invention and a control unit for controlling the driving of the fixing unit may vary according to a temperature change of the fixing unit. Generating a temperature detection signal based on a resistance value of a thermistor, outputting a comparison signal according to a difference between a potential of the temperature detection signal and a preset reference signal, and resetting the controller to initialize the control unit in response to the comparison signal Outputting a signal.

According to such an image forming apparatus and a driving method thereof, when the surface of the fixing unit is overheated, heating of the fixing unit is prevented by the control of the control unit and hardware control, and the control unit is initialized when the control unit is abnormally driven. By doing so, the heating of the heating lamp of the fuser can be cut off in advance, thereby preventing damage to the internal parts of the fuser and occurrence of fire.

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

FIG. 2 is a block diagram schematically illustrating an image forming apparatus according to an embodiment of the present invention, and FIG. 3 is a circuit diagram illustrating a specific embodiment of the fixing unit driver shown in FIG. 2. In particular, FIG. 2 illustrates a fuser and a control device of the fuser, and other portions are omitted.

2, the image forming apparatus 100 according to an embodiment of the present invention includes a control unit 110, a fixing unit 120, a power supply unit 130, a fixing unit driver 140, a temperature sensing unit 150, The protection circuit unit 160, the reset circuit unit 170, and the temperature comparison unit 180 are included.

In detail, the controller 110 controls the overall driving of each unit of the image forming apparatus. In particular, the control unit 10 is, for example, PWM so that the surface temperature of the fixing unit 120 is formed to the surface temperature of the preset temperature range in the driving mode of the fixing unit 120, for example, the setup mode, the standby mode and the printing mode. The surface temperature of the fixing unit 120 is controlled using a control method or the like.

In addition, when the power supply voltage is applied to the fixing unit 120 at a duty ratio of 100% in order to reduce the first printing output time (FPOT) in the setup mode, the control unit 110 has a surface temperature of the fixing unit 120. The control is performed so as not to be over shooting due to exceeding the heat resistance temperature of 120.

Although not shown, the fixing unit 120 includes a heating lamp for forming the surface temperature of the fixing unit 120 at a high temperature in order to fuse the image formed on the printing medium to the printing medium.

The power supply unit 130 may be formed of, for example, a switching mode power supply (SMPS), and the SMPS rectifies and smoothes an AC power input from the outside or forms an image by controlling the potential thereof. Supply the supply voltage to each part of the device.

The fuser driver 140 is selectively activated under the control of the controller 110 to control the power supply voltage output from the power supply unit 130 to the fuser 20. To this end, the fuser driver 140 may be formed as shown in FIG. 3, for example.

Referring to FIG. 3, the fixing unit control unit 140 controls the first switching unit 142 and the control signal CS to control the AC power AC_IN output from the power supply unit 130 to be selectively applied to the fixing unit 120. The second switch 144 is activated by the second switch 144 to control the activation of the first switch 142.

The first switching unit 142 may be formed of a switching element such as a triac (TRIAC). The second switching unit 144 may be formed as a photo coupler activated by the control signal CS. The photo coupler of the second switching unit 144 may be a light emitting element D1 such as a light emitting diode and a light receiving element PTA such as a photo-triac (PHOTO-TRIAC, PTA) that is coupled and activated with the light emitting element D1. It is composed.

The light emitting device D1 generates predetermined light according to the driving of the transistor TR1 that is selectively turned on by the control signal CS input under the control of the controller 110. The generated light is incident on the light receiving receiver PTA to activate the light receiving element PTA, and as the light receiving element PTA is activated, a movement path of current is formed. To this end, one end of the light emitting element D1 is connected to one end of the transistor TR1, and the light receiving element PTA is provided at a corresponding position of the light emitting element D1.

The first switching unit 142 is activated in conjunction with the activation of the second switching unit 144. That is, as the light receiving element PTA is conducted, AC power output from the power supply unit 130 is activated to be supplied to the fixing unit 120 to form a current path.

In addition, the fuser driver 140 may include a noise preventing part formed of resistors and capacitors R1 and C1 to reduce noise such as sparks generated when the first switching part 142 is activated, and the second switching part. It may further include a current limiting portion formed of the resistance element (R2) to reduce the amount of current applied to the (144).

Here, the fixing unit 120 includes a heating lamp 122. The heating lamp 122 converts AC power, that is, electrical energy, input from the power supply unit 130 into thermal energy. Such a heating lamp may be formed of, for example, a halogen lamp.

Referring back to FIG. 2, the temperature sensing unit 150 detects the surface temperature of the fixing unit 120 and corresponds to the surface temperature of the fixing unit 120 so that the controller 110 controls the surface temperature of the fixing unit 120. A temperature detection signal having a potential to be output is output. To this end, the temperature sensing unit 150 may include a temperature sensor such as a thermistor whose resistance value varies according to the surface temperature of the fixing unit 120. The apparatus may further include a signal generator (not shown) for generating a temperature detection signal using a look-up table or the like to output a temperature detection signal having a potential corresponding to the resistance value of the thermistor.

Here, the temperature sensing unit 150 may include, for example, a main thermistor and a sub thermistor. In this case, the main thermistor may be connected to the fixing unit driver 140 and used to detect the surface temperature of the fixing unit 120 for controlling the fixing temperature of the fixing unit 120. In addition, the sub thermistor detects the surface temperature of the fixing unit 120 to block heating of the fixing unit 120 when the surface temperature of the fixing unit 120 is formed at a temperature exceeding a preset temperature, for example, a heat resistance temperature. It can be used to

Although not shown, the protection circuit unit 160 may include a temperature detection signal 150, for example, a temperature detection signal output at a potential corresponding to a resistance value of the main thermistor, and a temperature exceeding a preset temperature, that is, a heat resistance temperature. The reference signal having a potential corresponding to the preset temperature is compared so that the surface temperature of the fixing unit 120 is not formed at an excess temperature. The comparison result is applied to the control unit 110. For example, when the comparison result indicates that the potential of the temperature detection signal is greater than the potential of the reference signal, the control unit 110 applies a comparison signal having a logic value of "1" to the control unit 110. 110 to control the driving of the fuser driver 140.

In addition, the protection circuit unit 160 may be hardware in preference to a control signal of a thermostat or the control unit 110 to prevent the surface temperature of the fixing unit 120 from being formed above a heat resistance temperature. And a temperature control device such as an H / W protector to block driving of the 120.

The reset circuit unit 170 operates in a state where the system is stabilized by stabilizing the clock signal in order to stabilize the power voltage applied from the power supply unit 130 to the controller 110 and to control the output timing of the synchronization signal required for the system. The control unit 110 is initialized by outputting a reset signal to the control unit 110 to start the operation.

In particular, the reset circuit unit 170 according to an embodiment of the present invention generates a reset signal forcibly resetting the controller 110 based on the comparison signal output from the temperature comparator 180.

The temperature comparison unit 180 may include a temperature detection signal formed based on a resistance value corresponding to the surface temperature of the fixing unit 120 formed in the temperature sensing unit 150, that is, the resistance value of the sub-thermistor, and the predetermined predetermined potential. The reference signal is compared and the comparison signal is output. Here, the comparison signal may be output when the potential of the reference signal is relatively high relative to the potential of the temperature detection signal, and the comparison signal is provided to the reset circuit unit 170, and the reset circuit unit 170 is provided to the comparison signal. Generate and output a reset signal.

The reset circuit unit 170 and the temperature comparison unit 180 will be described in more detail as follows.

4 is a circuit diagram illustrating a specific embodiment of the temperature comparison unit and the reset circuit unit illustrated in FIG. 2, FIG. 5 is a diagram illustrating a normal reset timing of the image forming apparatus illustrated in FIG. 2, and FIG. 2 is a diagram showing abnormal reset timing of the image forming apparatus shown in FIG.

2 to 4, the reset circuit unit 170 of the image forming apparatus 100 according to an embodiment of the present invention includes a reset IC U2 connected to the reset terminal nReset of the controller 110. do. At this time, the reset IC U2 is based on the comparison signal input to the input terminal In connected to the output terminal of the temperature comparator 180 and the reset terminal nReset of the controller 110 to the input terminal In. And an output terminal (Out) for outputting a reset signal generated by the ground and a ground terminal connected to the ground electrode.

The temperature comparator 180 is applied with a negative input terminal (-) to which a reference signal is applied and a temperature detection signal is formed based on a resistance value formed according to a temperature change of the fixing unit 120 in the temperature sensing unit 150. It may include a comparator circuit (U1) having a positive input terminal (+).

The reference signal formed by dividing the DC power supply Vcc to a predetermined level is applied to the negative input terminal (−). To this end, resistance elements R7 and R8 connected in series to the DC power supply Vcc are connected to the negative input terminal (−). For example, the reference signal may determine the resistance ratio of the resistance elements R7 and R8 and the potential of the DC power supply Vcc to have a potential level of 1V. Here, the reference signal is preferably formed to have a potential corresponding to the heat resistance temperature of the fixing unit 110, and forming the potential level of the above-described reference signal at 1 V means that the potential corresponding to the heat resistance temperature is set to one. . It is obvious that such dislocation levels can be formed in various ways.

The positive input terminal (+) is connected to the temperature sensing unit 150 and the resistance elements R9 and R10 connected in series and in parallel to the temperature sensing unit 150. In this case, the positive input terminal (+) may be connected to the sub thermistor Rth ₂ of the temperature sensing unit 150. The positive input terminal + receives a temperature detection signal in which the DC power supply Vcc is divided by the resistance value which varies with the temperature of the resistors R9 and R10 and the sub thermistor Rth ₂ . Therefore, the potential of the temperature detection signal is determined by the potential of the DC power supply Vcc and the variable resistance value of the temperature sensing unit 150.

For example, when the temperature sensing unit 150 includes a sub thermistor Rth ₂ having negative characteristics, the resistance value of the sub thermistor Rth ₂ exceeds the heat resistance temperature, and the resistance below the heat resistance temperature. It is formed with a low resistance value compared to the value. Therefore, when the surface temperature of the fixing unit 120 exceeds the heat resistance temperature, the potential level of the temperature detection signal input to the positive input terminal (+) decreases. As described above, in order for the DC power supply Vcc to be applied to the temperature detection signal based on the resistance value of the sub thermistor Rth ₂ , the resistance element R4 preferably uses a resistance element having a relatively high resistance value. Do.

Here, the temperature detection signal may be variably formed to have a value greater than or equal to the potential of the reference signal by the resistance ratio of the resistance elements R9 and R10 and the sub thermistor Rth ₂ below the heat resistance temperature.

The comparator circuit U1 compares the reference signal applied to the negative input terminal (-) with the temperature detection signal applied to the positive input terminal (+), and an example in which the potential of the temperature detection signal exceeds the potential of the reference signal is given. For example, the comparison signal of the logic value "1" is output.

In this case, the above-described reset circuit unit 170 generates a reset signal based on the comparison signal of the logic value "1", and provides the generated reset signal to the controller 110.

The controller 110 is initialized whenever a reset signal is output from the reset circuit unit 170.

Unexplained reference numeral 140a is a part of the fuser driver 140 not shown in the fuser driver 140 shown in FIG. 3, and is connected to, for example, a main thermistor Rth ₁ of the temperature sensing unit 150. The control signal CS for controlling the fuser driver 140 shown in FIG. 3 is output based on the resistance value of the main thermistor Rth ₁ and the fuser on signal Fuser_On signal output from the controller 110. do.

Looking at the process in which the control unit 110 of the fixing unit 100 having such a structure is initialized in more detail using a timing diagram as follows.

Referring to FIG. 5, when the surface temperature of the fixing unit 120 of the image forming apparatus 100 is normally controlled by the controller 110, when a power supply voltage is supplied from the power supply unit 130, the DC power supply Vcc is accordingly supplied. ) Is also generated. A reference signal obtained by dividing the DC power supply Vcc into the negative input terminal (−) of the comparator circuit U1 by the resistance elements R7 and R8 of the temperature comparator 180 is input, for example, at a potential of 1V. do.

Since the surface temperature of the fixing unit 120 is not overshooted by the control of the controller 110, the surface temperature of the fixing unit 120 is formed below the heat resistance temperature, and the resistance value of the sub thermistor Rth ₂ is high. It is formed with a resistance value. Accordingly, a temperature detection signal in which the DC power supply Vcc is divided by the resistors R9 and R10 and the sub thermistor Rth ₂ is generated and input to the positive input terminal + of the comparator circuit U1. At this time, since the temperature detection signal is input to the positive input terminal + based on the DC power supply Vcc, the temperature detection signal having a potential exceeding the potential of the DC power supply Vcc cannot be input. In addition, since the temperature detection signal is less than the heat resistance temperature, the resistance ratio may be variably formed to have a value greater than or equal to the potential of the reference signal by the resistance ratios of the resistance elements R9 and R10 and the sub thermistor Rth ₂ . The temperature detection signal input to the terminal (+) may be formed at, for example, 1V to Vcc potential range below the heat resistance temperature.

As described above, when the temperature detection signal and the reference signal are applied to the positive input terminal (+) and the negative input terminal (-), respectively, the comparator circuit U1 compares them, and as a result of comparison, the potential of the temperature detection signal Since the potential is relatively higher than the potential, a comparison signal having a logic value of "1" is generated and output. At this time, the reset IC U2 of the reset circuit unit 170 generates a reset signal in response to the comparison signal, and outputs the reset signal after a predetermined time (about 150 ms) is delayed due to the characteristics of the device. Accordingly, the controller 110 is initialized to start the operation in a state where the clock signal and the power supply voltage are stabilized to control the driving of the fuser driver 140.

Referring to FIG. 6, in a case where an abnormal state in which the surface temperature of the fixing unit 120 of the image forming apparatus 100 is not controlled by the controller 110, when a power voltage is supplied from the power supply 130, a direct current may be performed accordingly. A power source Vcc is also generated. The reference signal obtained by dividing the DC power supply Vcc into the negative input terminal (-) of the comparator circuit U1 by the resistance elements R7 and R8 of the temperature comparator 180 is input, for example, at a potential of 1V. do.

When the controller 120 operates abnormally, the surface temperature of the fixing unit 120 is formed to be a temperature exceeding the heat resistance temperature, so that the resistance value of the sub thermistor Rth ₂ is formed to a low resistance value. Accordingly, as shown at point A, the DC power supply Vcc is divided at the positive input terminal + of the comparator circuit U1 by the resistor elements R9 and R10 and the sub thermistor Rth ₂ . The detection signal is input, and the potential of the temperature detection signal falls to the potential of the reference signal, for example, less than 1 V as the resistance value of the sub thermistor Rth ₂ has a low resistance value. Therefore, the comparison signal output from the comparator circuit U1 is output with a logic value of zero.

At this time, since the control unit 120 is initialized by the reset signal output from the reset IC U2 before the point A, the control unit 120 turns off the driving of the heating lamp inside the fuser during the period between the point A and the point B. .

The surface temperature of the fixing unit 120 decreases with time, and when the point B is reached, the resistance value of the sub thermistor Rth ₂ is formed to a high resistance value. Accordingly, the temperature detection signal obtained by dividing the DC power supply Vcc by the resistance elements R9 and R10 and the sub thermistor Rth ₂ is input to the positive input terminal + of the comparator circuit U1, and the point B is input. As shown in FIG. 5, the potential of the temperature detection signal rises, for example, in the range of 1 V to Vcc as the resistance of the sub thermistor Rth ₂ has a high resistance.

In this way, when the potential of the temperature detection signal rises, the comparator circuit U1 outputs a comparison signal having a logic value of "1" again. Accordingly, the reset IC U2 resets the control unit 110 by outputting the reset signal of the logic value "1" again at the point C at which the predetermined delay time 150ms has elapsed.

Through the repetition of the above operation, when the controller 110 performs abnormal operation due to static electricity generated between the print medium such as printing paper and the fuser 120, the controller 110 is repeatedly initialized to fix the fuser 110. To prevent heating of the heating lamp.

In FIG. 6, an example in which the control unit 110 of the fixing unit operates abnormally during the initial driving of the image forming apparatus 100 is described as an example. However, even when an abnormal operation of the controller 110 occurs during the driving of the image forming apparatus 100, the controller 110 may be easily initialized based on the matters described in the present specification. .

As described above, according to the present invention, according to the image forming apparatus and the driving method thereof, when the surface of the fixing unit is overheated, heating of the fixing unit is prevented by the control of the control unit and the hardware control, and the control unit is abnormal. In the case of driving by the controller, the heating of the heating lamp of the fixing unit may be blocked in advance by initializing the control unit, thereby preventing damage to the internal parts of the fixing unit and the occurrence of fire.

While the foregoing has been described with reference to preferred embodiments of the present invention, those skilled in the art will be able to make various modifications and changes to the present invention without departing from the spirit and scope of the invention as set forth in the claims below. Will understand.

Claims (6)

An image forming apparatus comprising a fixing unit and a control unit for controlling driving of the fixing unit, A temperature sensing unit having a resistance value that varies with temperature change of the fixing unit; A temperature comparator for outputting a comparison signal according to a difference between a temperature detection signal formed on the basis of a resistance value of the temperature sensing unit and a preset reference signal; And And a reset circuit unit for outputting a reset signal for initializing the control unit in response to the comparison signal. The method of claim 1, wherein the temperature comparison unit, And a comparator circuit having a positive input terminal to which the temperature detection signal is input and a negative input terminal to which the reference signal is applied. The method of claim 1, wherein the reset circuit unit, And an integrated circuit having an input terminal to which the comparison signal is applied and an output terminal to which the reset signal is output. According to claim 1, wherein the temperature sensing unit The main thermistor for detecting the temperature of the fuser to form the temperature of the fuser, and the sub for detecting the temperature of the fuser to prevent the fuser from overheating Including thermistor, And the temperature detection signal is formed based on a resistance value of the sub thermistor. The image forming apparatus of claim 1, wherein the reference signal is a potential corresponding to a heat resistant temperature of the fixing unit. A driving method of an image forming apparatus having a fixing unit and a control unit for controlling driving of the fixing unit, Generating a temperature detection signal based on a resistance value of a thermistor which fluctuates with a temperature change of the fixing unit; Outputting a comparison signal according to a difference between a potential of the temperature detection signal and a preset reference signal; And And outputting a reset signal for initializing the control unit in response to the comparison signal.

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