JP2012093613A5 - Printing device, fixing device, and temperature control device for fixing device - Google Patents

Description

One embodiment of the present invention relates to a temperature control device for a fixing device used in a printing device or the like. In particular, the temperature of a heat source such as a heating roller is detected using a plurality of non-contact thermistors, and according to the detection result. The present invention relates to a printing apparatus, a fixing apparatus, and a temperature control apparatus for a fixing apparatus that control a heat source to an appropriate temperature.

2. Description of the Related Art Conventionally, in so-called electrophotographic image forming apparatuses, image formation is performed by forming a toner image on a photosensitive drum as an image carrier and transferring the toner image to a sheet material to form an image on the surface of the sheet material. and parts, and a fixing unit for fixing by welding the toner on the sheet material surface by heating the toner image formed on the sheet material downstream thereof, are provided.

In one embodiment of the present invention, even if the differential amplifier malfunctions due to noise or the like, the output becomes an abnormal value, and the temperature calculation is temporarily disabled, the temperature is controlled so as not to affect the control of the entire printing apparatus. The present invention provides a printing apparatus, a fixing apparatus, and a temperature control apparatus for the fixing apparatus that can provide a calculated value.

In order to achieve the above object, one aspect of the printing apparatus of the present invention is a printing apparatus that performs printing on a recording medium, which is heated by radiant heat from an image forming unit, a conveying unit that conveys the recording medium, and a heating element. first thermistor and a second thermistor for measuring the temperature near the person first thermistor, said first one terminal and said second thermistor thermistor for measuring temperature of the heat absorbing member to be And a power supply for connecting the other terminal of the first thermistor and the other terminal of the second thermistor to a constant voltage power source through a predetermined resistor, respectively. A first extraction circuit that extracts a first voltage based on the resistance value of the first thermistor, a second extraction circuit that extracts a second voltage based on the resistance value of the second thermistor, and the first extraction circuit. A differential amplifying means for amplifying the difference between the voltage and the second voltage, the calculated temperature of the heating element based on an output of said differential amplifier means, the driving of the heating element based on the calculation result comprising processing means for controlling and, when said value the output is out of numerical values of a preset range of the differential amplifier means is identified, the processing means, the said first voltage second based of the voltage, and calculates the temperature of the heating element, and controls the driving of the heating element based on the calculation result, characterized in that.

In order to achieve the above object, one aspect of the fixing device of the present invention is a fixing device for fixing to a storage medium in a printing apparatus that performs printing on a recording medium, wherein the heat absorbing member is heated by radiant heat from a heating element. The first thermistor for measuring the temperature of the first thermistor, the second thermistor for measuring the temperature in the vicinity of the first thermistor, and the one terminal of the first thermistor and the one terminal of the second thermistor are both grounded. A power supply circuit for connecting the other terminal of the first thermistor and the other terminal of the second thermistor to a constant voltage power source through a predetermined resistor, and the first thermistor, respectively. A first extraction circuit that extracts a first voltage based on the resistance value of the second thermistor, a second extraction circuit that extracts a second voltage based on the resistance value of the second thermistor, the first voltage and the previous voltage A differential amplifying means for amplifying the difference from the second voltage; a process for calculating the temperature of the heating element based on the output of the differential amplifying means; and controlling the driving of the heating element based on the calculation result And when the output of the differential amplifier is out of a predetermined range, the processing means includes the first voltage and the second voltage. Based on the above, the temperature of the heating element is calculated, and the driving of the heating element is controlled based on the calculation result.

In order to achieve the object, one aspect of the temperature control device of the fixing device according to the present invention includes a heat absorbing member heated by radiant heat from a heating element, a first thermistor for measuring the temperature of the heat absorbing member, and the first thermistor. A second thermistor that measures a temperature in the vicinity of one thermistor, a ground circuit that connects one terminal of the first thermistor and one terminal of the second thermistor to a ground potential, and the first thermistor A power supply circuit for connecting the other terminal of the second thermistor and the other terminal of the second thermistor to a constant voltage power source via a predetermined resistor, respectively, and a first voltage based on the resistance value of the first thermistor A first extraction circuit; a second extraction circuit that extracts a second voltage based on a resistance value of the second thermistor; and differential amplification means that amplifies a difference between the first voltage and the second voltage; Previous Processing means for calculating the temperature of the heating element based on the output of the differential amplifying means, and controlling the driving of the heating element based on the calculation result. When a value outside the set range is identified, the processing means calculates the temperature of the heating element based on the first voltage and the second voltage, and the calculation result The driving of the heating element is controlled based on the above.

According to an embodiment of the present invention, even when a differential amplifier malfunctions due to noise or the like, an output becomes an abnormal value, and temperature calculation is temporarily disabled, control of the entire printing apparatus is not affected. temperature calculation value can be provided.

The image forming unit 2 has a configuration in which four image forming units 6 (6M, 6C, 6Y, 6K) are arranged in a multistage manner from right to left in FIG. The three image forming units 6M, 6C, and 6Y on the upstream side (the right side in the drawing) of the four image forming units 6 are magenta (M) and cyan (C ), A monochrome image is formed with yellow (Y) color toner, and the image forming unit 6K forms a monochrome image with black (K) toner mainly used for dark portions of characters and images.

The optical writing head 11 exposes an optical image corresponding to image information input from the outside via an interface (not shown) on the surface of the photosensitive drum 7 to form an electrostatic latent image. The image forming units 6M, 6C, 6Y, each optical writing head 11 in the 6K, magenta in the image information input from the outside, respectively, cyan, yellow, drive signal based on the data corresponding to the black color is supplied The light images corresponding to the respective colors are exposed to form latent images.

The intermediate transfer belt unit 3 has an endless transfer belt 14 arranged in a flat loop shape from substantially the left and right sides of the drawing at the center of the main body device, and the transfer belt 14 is stretched over the transfer belt 14. a drive roller 15 and driven roller 16 is circulated move the belt 14 in the counterclockwise direction in the figure, and a.

That is, the belt position control mechanism 17 sets the position of the transfer belt 14 of the intermediate transfer belt unit 3 in the full color mode (all four primary transfer rollers 18 are in contact with the transfer belt 14) and the monochrome mode (corresponding to the image forming unit 6K). Only the primary transfer roller 18 is in contact with the transfer belt 14) and all non-transfer modes (all four primary transfer rollers 18 are separated from the transfer belt 14), and the printer apparatus 1 performs the recording process. If not, the all-transfer mode state is set, and when the transfer belt 14 is disconnected from all the image forming units 6 and the printer apparatus 1 is in the monochrome print processing state, the transfer belt 14 is switched to the monochrome mode position. The relationship between the transfer belt 14 and the image forming units 6M, 6C, and 6Y for color printing is cut off. It has a configuration to prevent the exhaustion due to contact abrasion of the transfer belt 14 and the photosensitive drum 7.

The fixing unit 27 is a belt-type fixing unit. The fixing unit 27 includes guide plates 30a and 30b, a heating roller 40, a fixing roller 41, an endless fixing belt 42 stretched between the heating roller 40 and the fixing roller 41, and the fixing roller 41 via the fixing belt 42. the opposite is arranged a fixing roller 41 and fixing belt 42 provided with a pressure roller 43 for pressing the, the fixing roller 41 and the pressure roller 43, the cooperation with other units (the intermediate transfer belt unit 3) A paper transport system is formed.

The fixing unit 27 melts and fixes the toner image on the paper by applying heat and pressure to the toner image on the paper. Fixing method is a method of pressurizing with by thermally transfer heat of the heating roller 40 heated by the halogen heater 44 in the fixing belt 42 to the fixing roller 41, also the fixing roller 41 and the pressure roller 43. Note that the pressing force on the pressure roller 43 side has a function to vary depending on the type of paper.

The non-contact type temperature sensor 53 used in the present invention detects the surface temperature of the fixing belt 42 by detecting infrared rays radiated from the surface of the fixing belt 42 heated by the heating roller 40. An infrared detection thermistor T1 and a temperature compensation thermistor T2 are provided inside. The infrared detecting thermistor T1 detects the temperature of the infrared absorbing film heated by the infrared rays radiated from the surface of the fixing belt 42, and the output voltage depends on the ambient temperature. In order to compensate for such temperature dependence, it is necessary to detect the temperature of the infrared detection thermistor T1 itself. For this reason, the temperature compensation thermistor T2 is disposed in the vicinity of the infrared detection thermistor T1 at a position not affected by the infrared rays radiated from the surface of the fixing belt 42, and heating is performed by detecting the potentials at both ends of these two thermistors. The temperature of the surface of the fixing belt 42 heated by the roller 40 can be grasped.
The average value of the potential difference between the two thermistors is converted into a digital value by an A / D converter built in the CPU 49, and the converted digital value is input by the CPU 49 executing a predetermined program. The surface temperature of the fixing belt 42 is obtained based on the digital value and a predetermined table, and energization control of the halogen heater 44 and the halogen heater 45 included in the heating roller 40 is performed so that the surface temperature is maintained constant. . The specific control method will be described in detail below.

The control device 47 includes a CPU 49 that controls the entire printer apparatus 1 according to a control procedure stored in a read-only memory (ROM) 48, and a read-only memory (ROM) 48 that stores a control procedure (control program) of the control device 47. A random access memory (RAM) 51, which is a main storage device used as a storage area for input data, a working storage area, and the like; a control signal output from the CPU 49 for a load such as a main motor; and a signal from a sensor, etc. an interface unit (I / O) 52 for sending the CPU49 and includes a.

FIG. 4 is a diagram illustrating a configuration of a temperature control device of the fixing device using the non-contact temperature sensor 53 according to an embodiment of the present invention. 4, the non-contact temperature sensor 53, the sensing thermistor T1, the compensation thermistor T2, two thermistors are provided. The thermistor for detection is in contact with the infrared absorbing film 54 and is used for detecting the temperature of the heating roller 40. The infrared ray absorbing film 54 absorbs the infrared ray 50 from the heating roller 40 and converts it into heat energy, and the heat is detected by the detection thermistor T1. On the other hand, the compensation thermistor T2 is used to detect the temperature of the non-contact temperature sensor 53 itself. Temperature of the heating roller 40 utilizes the resistance value changed by the detected temperature of the sensing thermistor T1, the resistance value changes by detecting the temperature of the compensation thermistor T2, a, is calculated.

FIG. 5 is a circuit diagram of a temperature control device for a fixing device using the non-contact temperature sensor 53 according to an embodiment of the present invention. Two thermistors T1 and T2 incorporated in the non-contact temperature sensor 53 are connected to a power source (5V) by resistors R2 and R1, respectively, and a common terminal is connected to GND.
R2 and R1 are resistance elements having substantially the same resistance value. For example, both have a resistance value of 33 KΩ here. The resistance values of the detection thermistor T1 and the compensation thermistor T2 shown in FIG. 5 vary in the range of several K to several MΩ depending on the temperature, for example, the resistance value increases as the temperature decreases (for example, It has a resistance value of about 1 MΩ at a low temperature around 0 ° C.). Such compensation voltage V2 between the resistor R2 and the auxiliary償用thermistor T2 inputs is input to the positive terminal 57 of the differential amplifier 56 to the V2 value terminal on the A / D converter port CPU 49. Meanwhile, the detection voltage V1 applied between the resistor R1 and the detection knowledge thermistor T1 inputs is input to the negative terminal 58 of the differential amplifier 56 to the V1 value terminal on the A / D converter port CPU 49. Further, an offset voltage (for example, 0.5 V here) is applied to the differential amplifier 56. The differential amplifier 56 amplifies a differential voltage between the input detection voltage V1 and the compensation voltage V2, adds an offset voltage to the amplified voltage, and outputs a voltage Vdef. Therefore, when V1 and V2 are equal voltages, the differential voltage is 0, and an offset voltage of 0.5 V is output as the output Vdef of the differential amplifier 56. The output Vdef of the differential amplifier 56 is input to the difference value terminal of the A / D converter port of the CPU 49. An A / D (analog / digital) converter built in the CPU 49 converts Vdef, V1, and V2 from voltage values to digital values. The CPU 49 performs various control processes, for example, the calculation of the temperature of the heating roller 40, using the data digitized by the A / D converter.

The non-contact temperature sensor 53 according to an embodiment of the present invention includes a detection thermistor T1 and a compensation thermistor T2, and performs highly accurate temperature detection together with the following peripheral circuits. That is, a voltage, for example, 5V is applied by the constant voltage circuit 59 , and a voltage V1 between the detection thermistor T1 and the resistor R1 and a voltage V2 between the compensation thermistor T2 and the resistor R2 are generated. Are input to the differential amplifier 56. When the difference voltage obtained by subtracting V 2 from V 1 is estimated from a general measurement temperature range in which the temperature sensor 53 is used, it is estimated that the difference voltage is about 200 mV at the maximum. Therefore, the differential amplifier 56 amplifies the differential voltage. As an example, in the present embodiment, the gain of the differential amplifier 56 is set to 20 times. The differential amplifier 56 amplifies the differential voltage obtained by subtracting V 2 from V 1 and outputs a voltage Vdef obtained by adding the offset voltage. Therefore, for example, when the difference obtained by subtracting V 2 from V 1 is around the maximum 200 mV, (0.2V × 20) + 0.5V and 4.5V is output as the output Vdef of the differential amplifier 56. Will be. The output voltages Vdef and V2 are sent to the A / D converter port of the CPU 49, and the analog voltage is converted into a digital value by the A / D converter built in the CPU 49. In the CPU 49, a process of obtaining the temperature of the heating roller 40 by referring to a temperature table that is stored in the memory (RAM 51) using the digitized value and indicates the temperature relationship corresponding to the values of Vdef and V2. conducted, halogen heater 44 so that the temperature obtained is maintained at a pre desired fixing temperature, power supply amount to halo Gen heater 45 is controlled.

Further, the A / D converter of the CPU 49 used in the temperature control device of the present invention is a low-cost CPU and is a 10-bit type in which the number of operation digits is general, and therefore the resolution of the voltage value to be calculated is 5 mV. Yes.
However, in reality, the difference between V1 and V2 is about 200 mV at the maximum due to the characteristics of the non-contact temperature sensor 53, and the voltage change per 1 ° C. of temperature change is very small, about 1 mV.
Therefore, in the temperature control device of the present invention, the difference between the voltages V1 and V2 is amplified by the differential amplifier 56 (IC1), and together with V1 and V2, the difference value (Vdef signal) is obtained as an A / C value of CP U4 9. Input to D converter port.
The differential amplifier 56, since the set to 0.5V offset voltage as described above, the output is 0.5V when V1 and the V2 is the same voltage.

FIG. 6 is a flowchart showing a temperature control procedure performed by the CPU 49 included in the temperature control apparatus according to the embodiment of the present invention. Hereinafter, based on the flowchart of FIG. 6, the specific temperature control method which CPU49 processes is explained in full detail.
CPU49 is initially measured based on the voltage value inputted voltage value of the V1 and V2 that are inputted to the differential amplifier 56 to Oyobi V2 value terminal V1 value terminal of the A / D converter port ( Step (hereinafter referred to as S) S1). Since the temperature calculation is basically performed from the two thermistor voltages V1 and V2, as described above, first, the temperature calculation is performed from these V1 and V2 (S2).
However, as described above, since the difference between V1 and V2 is very small, the A / D converter with 10-bit resolution as used in this embodiment has a low resolution, and the values V1 and V2 are not used as they are. , Accurate temperature calculation is not possible. Therefore, here, the temperatures calculated by V1 and V2 are stored as temporary values (S3).

Next, the output (Vdef) of the differential amplifier 56 is measured, and the temperature is calculated from V2 and Vdef as described above (S4). Since the difference value Vdef amplifies a minute difference between V1 and V2 , even a 10-bit A / D converter (resolution of about 5 mV) used in this embodiment is affected by noise and the like. Unless it is normal, accurate temperature calculation can be performed, and when normal (S5 is NO), temperature control is performed based on this calculated value (S6).

On the other hand, as described above, the output (Vdef) of the differential amplifier 56 may become an abnormal value (0.5V or less or 4.5V or more as described above) due to the influence of noise or the like. There is no guarantee that the temperature calculation can be performed.
Therefore, in this embodiment, when the output (Vdef) of the differential amplifier 56 shows an abnormal value as described above (S5 is YES), the calculation is performed from V1 and V2, which are the temporary values in step S3. The temperature is adopted as the actual value instead of the temperature value obtained from the Vdef value (S9).

It is not a small voltage V1 and V2, not the malfunction as differential amplifier output values, since simple input, such as by a condenser, also noise countermeasure circuit manner is easy. For this reason, the reliability with respect to malfunction is higher than the output obtained from the differential amplifier 56. Therefore, although the accuracy is not good as described above, it is possible to avoid the output of an abnormal temperature far away due to noise, and the differential amplifier 56 exhibits an abnormal value as described above for a short time due to the influence of noise or the like. Therefore, there is almost no influence on external temperature control (such as heater temperature management), and the printing apparatus is not stopped.
In addition, when the differential amplifier 56 is really out of order because it is not a short-term failure due to the influence of noise or the like, this abnormal value is always output instead of temporarily. It is determined that the abnormal value continues for a certain time or more (S7 is YES), and it is notified that the circuit is abnormal (S8).

In the above-described embodiment, only when the output (Vdef) of the differential amplifier 56 is an abnormal value (0.5 V or less or 4.5 V or more), the value calculated by V1 and V2 is output. A malfunction may be considered in which the output (Vdef) of the dynamic amplifier 56 is not correct even if it is not an obvious abnormal value (the aforementioned 0.5 V or less or 4.5 V or more).
Another embodiment of the present invention in view of such cases, the input V1 and the V2 and value temperature calculated by the differential amplifier 56, a value obtained by the temperature calculated at the output of the differential amplifier 56 (Vdef), the Compare.
That is, as described above are at the input V1 and V2 of the differential amplifier 56, so subjected to precision, although a value obtained by the temperature calculated at the output of the differential amplifier 56 (Vdef) is little difference there, originally the same Since it is an element, it should have the same value.
Accordingly, if there is a certain difference between the two values, the CPU 49 determines that a correct value is not calculated due to a malfunction of the differential amplifier 56. In this case, the inputs V1 and V2 of the differential amplifier 56 are determined. If the difference between the two values is within a certain range, the CPU 49 determines that the value is an accurate value and outputs the temperature calculated value at the output of the differential amplifier 56. You may adopt the method of judgment.

On the other hand, in this embodiment, when the output (Vdef) of the differential amplifier 56 becomes an abnormal voltage (0.5 V or less or 4.5 V or more) (ST2 is NO), the Vdef value is not used and the differential amplifier 56 is used. measured on the basis of values of the V1 and V2 that are inputted to the voltage value input to the Oyobi V2 value terminal V1 value terminal of the a / D converter port to (ST5). The output of the differential amplifier 56 (Vdef) is to be generated from the difference between the input V1 and V2 of the differential amplifier, can of course calculate the same value as the output Vdef of the differential amplifier in the measurement value of V1 and V2. However, as described above, since the differential voltage is very small, the A / D converter with 10-bit resolution as used in the present invention has a low resolution and does not have an accurate value. However, it is not only an accurate value for use in temperature calculation, and it can be sufficiently determined whether or not it is an abnormal voltage (0.5 V or less or 4.5 V or more at the differential amplification output).

For example, as described above, V1 is larger than V2, and this determination is sufficiently possible even with a low-cost CPU having a resolution of about 10 bits. That is, the same determination as that in which the output (Vdef) of the differential amplifier 56 is 0.5 V or less is possible.
On the other hand, since the differential amplifier 56 is 4.5V or more, the offset voltage is 0.5V and the gain is 20 times, so the differential voltage between V1 and V2 is 0.2V or more (YES in ST7). Even a 10-bit A / D converter (resolution of about 5 mV) can be sufficiently judged.
Therefore, in the present embodiment, even if the differential amplifier 56 shows an abnormal value (0.5 V or less or 4.5 V or more), the abnormal amplifier is not immediately notified, and the differential amplifier 56 as described above. also from the input of the V1 and V2 Metropolitan to verify whether the difference is really abnormal value.
Less affected by noise for the input V1 and V2 of the differential amplifier 56 is not a small voltage, since a single voltage input, also easily performed, such as in noise suppression capacitor.
Therefore, even if the output (Vdef) of the differential amplifier 56 is an abnormal voltage, the difference calculation between V1 and V2 is abnormal, that is, unless (V1 <V2) (ST6 is NO), it is regarded as the influence of noise, and the abnormality notification is performed. Not performed (ST9).
Of course, the input V1 and V2 and by the difference calculation of the differential amplifier 56 ((V1-V2)> 0.2V) case (ST7 is YES) Outlier regarded as truly circuit abnormality, the abnormality notification (ST8 ).

Claims (11)

A printing apparatus for printing on a recording medium,
Image forming means;
Conveying means for conveying the recording medium;
A second thermistor for measuring the first thermistor and the temperature near the person first thermistor for measuring the temperature of the heat absorbing member is heated by radiant heat from the heating element,
A ground circuit that connects one terminal of the first thermistor and one terminal of the second thermistor to a ground potential;
A power supply circuit for connecting the other terminal of the first thermistor and the other terminal of the second thermistor to a constant voltage power source via a predetermined resistor, respectively;
A first extraction circuit for extracting a first voltage based on a resistance value of the first thermistor;
A second extraction circuit for extracting a second voltage based on a resistance value of the second thermistor;
A differential amplifying means for amplifying a difference between the first voltage and the second voltage,
Processing means for calculating the temperature of the heating element based on the output of the differential amplification means, and controlling the driving of the heating element based on the calculation result ;
Equipped with a,
If the value the output of said differential amplifier means is outside the numerical range set in advance is identified,
The processing means calculates the temperature of the heating element based on the first voltage and the second voltage, and controls the driving of the heating element based on the calculation result .
A printing apparatus characterized by that. Claim 1, wherein the output of said differential amplifier means when disengaged a number between said preset continues for a predetermined time comprises informing means for informing a temperature abnormality of the heating element The printing apparatus as described. The processing means, the differential said temperature value is calculated on the basis of the output of the amplifying means and said first voltage and a predetermined or more difference between the temperature value calculated based on the second voltage The printing apparatus according to claim 1, further comprising a notification unit configured to notify a temperature abnormality of the heating element when there is a temperature. The printing apparatus according to claim 1, wherein the first thermistor and the second thermistor are non-contact temperature sensors. 3. The printing apparatus according to claim 1, wherein the second thermistor is disposed at a position not affected by the radiant heat from the heating element. The printing apparatus according to claim 1, wherein the heating element is a halogen heater. The printing apparatus according to claim 1, wherein the heat absorbing member is an infrared absorbing film. The differential amplifying means amplifies the difference voltage between the voltage supply terminal potential of the first thermistor and the voltage supply terminal potential of the second thermistor by a predetermined magnification. Item 6. The printing apparatus according to any one of Items 1 to 5. An offset voltage is input to the differential increase means,
The differential amplifying means converts the magnitude of the differential voltage between the potential of the voltage supply terminal of the first thermistor and the potential of the voltage supply terminal of the second thermistor to a voltage obtained by amplifying the offset voltage by the predetermined magnification. The printing apparatus according to claim 6, wherein a voltage obtained by adding is output to the processing unit. A fixing device for fixing to a storage medium in a printing apparatus for printing on a recording medium,
A first thermistor that measures the temperature of the heat absorbing member that is heated by radiant heat from the heating element, and a second thermistor that measures the temperature near the first thermistor;
A ground circuit that connects one terminal of the first thermistor and one terminal of the second thermistor to a ground potential;
A power supply circuit for connecting the other terminal of the first thermistor and the other terminal of the second thermistor to a constant voltage power source via a predetermined resistor, respectively;
A first extraction circuit for extracting a first voltage based on a resistance value of the first thermistor;
A second extraction circuit for extracting a second voltage based on a resistance value of the second thermistor;
Differential amplification means for amplifying a difference between the first voltage and the second voltage;
Processing means for calculating the temperature of the heating element based on the output of the differential amplification means, and controlling the driving of the heating element based on the calculation result;
With
When the output of the differential amplifying means is identified as a value out of a preset range,
The processing means calculates the temperature of the heating element based on the first voltage and the second voltage, and controls the driving of the heating element based on the calculation result.
A fixing device. A heat absorbing member heated by radiant heat from the heating element;
A first thermistor for measuring the temperature of the heat absorbing member and a second thermistor for measuring the temperature in the vicinity of the first thermistor;
A ground circuit that connects one terminal of the first thermistor and one terminal of the second thermistor to a ground potential;
A power supply circuit for connecting the other terminal of the first thermistor and the other terminal of the second thermistor to a constant voltage power source via a predetermined resistor, respectively;
A first extraction circuit for extracting a first voltage based on a resistance value of the first thermistor;
A second extraction circuit for extracting a second voltage based on a resistance value of the second thermistor;
Differential amplification means for amplifying a difference between the first voltage and the second voltage;
Processing means for calculating the temperature of the heating element based on the output of the differential amplification means, and controlling the driving of the heating element based on the calculation result;
Have
When the output of the differential amplifying means is identified as a value out of a preset range,
The processing means calculates the temperature of the heating element based on the first voltage and the second voltage, and controls the driving of the heating element based on the calculation result.
A temperature control device for a fixing device.