JP4066125B2 - Fail-safe circuit and image forming apparatus - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention belongs to the technical field of a fail-safe circuit capable of preventing abnormal operation even when a power supply failure occurs, and an image forming apparatus including the circuit.
[0002]
[Prior art]
  A conventional image forming apparatus such as a printer includes a fixing device for performing heat fixing and a temperature control mechanism for maintaining the temperature of the fixing device at an appropriate fixing temperature.
[0003]
  The temperature control mechanism includes a temperature detection means such as a thermistor for detecting the temperature of the fixing device, a comparator as a comparison means for comparing an output signal from the temperature detection means and a reference signal, and an output signal from the comparison means. And a control means for controlling on / off of the heater of the fixing device based on the above. The temperature detection means generates an output signal having a value (voltage value) proportional to the temperature of the fixing device, and the reference signal is output from a control means including a microprocessor to a comparator. A value (voltage value) corresponding to the target temperature of the fixing device is shown. The comparator determines the magnitude (voltage value) of both signals, and when the temperature of the fixing device becomes higher than the target temperature, it outputs a low level signal to the control means as a target arrival signal, and controls accordingly. The means stops heating the fixing device. On the other hand, when the temperature of the fixing device is lower than the target temperature, the comparator outputs a high-level signal as a target non-reaching signal to the control means, and the control means heats the fixing device accordingly.
[0004]
  With such a configuration, the temperature of the fixing device can be appropriately maintained, and an image with good image quality can be formed.
[0005]
[Problems to be solved by the invention]
  However, in the conventional method, a power supply voltage of 3.3 V is supplied to the control means, and a power supply voltage of 5 V different from this power supply voltage is supplied to the comparator in order to ensure a stable operating range. Therefore, when the 5V power supply failure occurs, an abnormal operation has occurred in the control means. Note that 5V is used as the power supply for the comparator. The supply voltage of -1.5V is the normal comparator operating range. When the supply voltage of 3.3V is used, only the operating range of 1.8V can be obtained. The range becomes narrower. For this reason, the temperature detection range of the thermistor for temperature detection becomes rough, and accurate temperature control cannot be performed by finely detecting the temperature.
[0006]
  In other words, in the conventional apparatus, an open collector or open drain output comparator is used, and the output of this comparator is pulled up to 3.3 V and input to the control means. However, a voltage of H (High) level is supplied to the control means. Therefore, in this case, regardless of the temperature change of the fixing device, an H (High) level voltage (target non-reaching signal) is continuously input to the control means, and the control means heats the fixing device. Subsequently, proper temperature control could not be performed. In order to prevent this, if the control means detects that the target non-reaching signal is input even after heating for a predetermined time, it may be possible to adopt control that determines that a failure has occurred, but the fixing device is already hot. In addition, when the 5V power supply is lost, the fixing device may be further heated during the predetermined time and may be broken.
[0007]
  The present invention solves the above-described problems and provides a fail-safe circuit that does not cause an abnormal operation even when a power supply failure to a comparison unit occurs and an image forming apparatus including the circuit. Is an issue.
[0008]
[Means for Solving the Problems]
  In order to solve the above problem, the fail-safe circuit according to claim 1 is driven by a first power supply having a first voltage value, and the control amount is controlled when the input signal is an on-potential that is distinguished from the ground potential. Driven by a control means for controlling the control target so as to increase, and a second power source having a second voltage value different from the first voltage value, and a signal corresponding to the state of the control target is the input signal As a signal output means for outputting to the control means, one end connected to the signal output section of the signal output means and the signal input section of the control means, and the other end connected to the second power source And a pull-down resistor having one end connected to the signal output unit of the signal output unit and the signal input unit of the control unit and the other end grounded, and when the second power source is lost, Pull down resistor And it is supplied to the control means a signal that has been ground as the input signal, characterized in that stopping the control of the controlled object by the control means.
[0009]
  According to the fail-safe circuit of the first aspect, the control means is driven by the first power supply having the first voltage value, and stops the control of the controlled object when the ground potential signal is supplied. . Further, when an on-potential signal having a potential different from the ground potential is supplied, the control amount for the controlled object is increased. The ground potential signal and the ON potential signal are supplied to the control means by a signal output means driven by a second power source having a second voltage value different from the first voltage value. The connection line between the signal output unit of the signal output unit and the signal input unit of the control unit has a pull-up resistor whose one end is connected to the second power source and one end connected to the second power source. The other end of the resistor is connected. Therefore, even when the second power supply is lost, a signal of the ground potential is supplied to the signal input portion of the control means via the pull-down resistor. As a result, the control means stops the control of the control object as described above, so that the control abnormality in the control object is prevented.
[0010]
  The fail-safe circuit according to claim 2, wherein the signal output means is means for comparing signals, and the control means is the signal output means in order to solve the problem. It is a means which controls a control object based on the input signal from.
[0011]
  According to the fail safe circuit of the second aspect, since the signal output means is means for comparing signals, it is necessary to ensure a wider operating range than other means. Therefore, the absolute value of the second voltage value in the second power source that drives the signal output means is set to a value larger than the absolute value of the first voltage value of the first power source. As a result, when the signal output unit of the signal output means driven by the second power supply is in a high impedance state when the second power supply is lost, the second power supply is driven by the first power supply. There is a possibility that a signal that can be determined as the on-potential signal in the control means is input to the signal input section of the control means.
[0012]
  Here, since the control means is a means for controlling the control target based on the input signal from the signal output means, when a signal that can be determined as the on-potential signal is input, the control amount of the control target Even if it is not necessary to increase the control amount, the control means may increase the control amount of the control target.
[0013]
  However, the fail-safe circuit of the present invention inputs a ground potential via a pull-down resistor to the signal input unit of the control means when the second power supply is lost. As a result, the control means stops the control of the control object as described above, so that the control abnormality in the control object is prevented.
[0014]
  In order to solve the above-mentioned problem, the fail-safe circuit according to claim 3 is the fail-safe circuit according to claim 2, wherein the signal output means outputs a temperature signal based on a temperature of a heating device as a control target and a target temperature. And a reference signal based on the reference signal, and when the temperature corresponding to the temperature signal is lower than the target temperature, the signal output is an on-potential signal that is distinguished from the ground potential, and the control means outputs the signal output When the input signal from the means is an on-potential, the temperature is controlled so as to increase the temperature of the heating device.
[0015]
  According to the failsafe circuit of claim 3, the temperature signal based on the temperature of the heating device and the reference signal based on the target temperature are compared in the signal output means, and the temperature corresponding to the temperature signal is lower than the target temperature. When it is low, an on-potential signal that is distinguished from the ground potential is output from the signal output means to the control means. In this case, the control means controls so as to raise the temperature of the heating device when the input signal from the signal output means is an ON potential.
[0016]
  Further, a temperature signal based on the temperature of the heating device and a reference signal based on the target temperature are compared in the signal output means, and when the temperature corresponding to the temperature signal is higher than the target temperature, a signal of the ground potential is It is output from the signal output means to the control means, and the control means controls so as not to raise the temperature of the heating device.
[0017]
  Therefore, when the second power supply is lost, a signal in a high impedance state is output from the signal output means regardless of the temperature signal. At this time, the control means is connected to the pull-down resistor. Therefore, the control means controls so as not to raise the temperature of the heating device. As a result, it is possible to prevent a control abnormality that erroneously operates the heater when the target temperature has already been reached.
[0018]
  The image forming apparatus according to claim 4, in order to solve the problem, an image forming unit for forming an image on a recording medium, a first power source for supplying a first voltage value, and the first power source. When the target attainment signal indicating that the target state of the control target has been supplied is supplied and the target attainment signal indicating that the target state of the control target has not been reached is supplied And a second power source that supplies a second voltage value different from the first voltage value, and a second power source that is driven by the second power source, depending on the state of the control target. Signal output means for supplying the target reaching signal or the target unreached signal to the control means,One end is connected to the signal output unit of the signal output unit and the signal input unit of the control unit, the other end is connected to the second power source, and one end is a signal of the signal output unit. A pull-down resistor connected to the output unit and the signal input unit of the control unit and having the other end grounded, and a signal supplied to the control unit when the second power supply is lost is transmitted via the pull-down resistor. Grounded potentialAnd fail-safe means for fixing to the target arrival signal.
[0019]
  According to another aspect of the image forming apparatus of the present invention, the control unit is driven by the first power source having the first voltage value, and the target indicating that the control target included in the image forming unit has reached the target state. When the arrival signal is supplied, the operation of the controlled object is stopped. In addition, when a target non-reaching signal indicating that the control target has not yet reached the target state is supplied, the control target is activated. The target reaching signal and the target non-reaching signal are supplied to the control means by signal output means driven by a second power supply having a second voltage value different from the first voltage value. A fail safe means is connected to a connection line between the signal output portion of the signal output means and the signal input portion of the control means. This fail-safe means isOne end is connected to the signal output unit of the signal output unit and the signal input unit of the control unit, the other end is connected to the second power source, and one end is a signal of the signal output unit. A pull-down resistor connected to the output unit and the signal input unit of the control unit and having the other end grounded, and a signal supplied to the control unit when the second power supply is lost is transmitted via the pull-down resistor. The target arrival signal of the grounded potentialSecure to. As a result, the control unit stops the operation of the control target as described above, so that a control abnormality in the control target included in the image forming unit is prevented.
[0020]
  The image forming apparatus according to claim 5, further comprising a detecting unit that detects a state of a control target and supplies a detection signal to the image forming apparatus according to claim 4. The means supplies the target arrival signal or the target unreachable signal based on the detection signal and a signal corresponding to the target value to be controlled.
[0021]
  According to the image forming apparatus of claim 5, the state of the control target is supplied to the signal output unit as a detection signal by the detection unit, and the signal output unit corresponds to the detection signal and a target value of the control target. Based on the signal, the target attainment signal or the target unattainment signal is supplied. Therefore, when the control target has reached the target value when the second power source is lost, the detection means supplies a detection signal indicating that to the signal output means, but the signal output means Is stopped due to the loss of the second power source. However, when the second power source is lost, the potential of the signal input unit of the control unit is fixed to a value equal to the potential of the target arrival signal by the fail safe unit. As a result, the control means stops the operation of the control object as described above, so that the control object that has already reached the target value is not erroneously caused to erroneously reach the target value, and the image formation is not performed. Control abnormality in the controlled object included in the means is prevented.
[0022]
  6. The image forming apparatus according to claim 6, wherein, in order to solve the above-described problem, in the image forming apparatus according to claim 5, the image forming unit fixes the developer image on the recording material by heating with a heater. A temperature detecting means for detecting the temperature of the fixing device as the detecting means, and the control means uses the heater as the control target and indicates that the temperature in the fixing device has reached a target temperature. Means for stopping the operation of the heater when the target attainment signal is supplied and for operating the heater when the target unattainment signal indicating that the temperature in the fixing device has not reached the target temperature is supplied And the fail-safe means isOne end is connected to the signal output unit of the signal output unit and the signal input unit of the control unit, the other end is connected to the second power source, and one end is a signal of the signal output unit. A pull-down resistor connected to the output unit and the signal input unit of the control unit and having the other end grounded, and a signal supplied to the control unit when the second power supply is lost is transmitted via the pull-down resistor. Grounded potentialIt is means for fixing to the target arrival signal.
[0023]
  According to the image forming apparatus of the sixth aspect, the first voltage value having the first voltage value from the signal output means driven by the second power source having the second voltage value based on the temperature detected by the temperature detection means. When a target arrival signal indicating that the fixing device has reached the target temperature is supplied to the control means driven by the power source, the control means stops the operation of the heater of the fixing device. Further, when a target non-reaching signal indicating that the fixing device has not yet reached the target temperature is supplied from the signal output means to the control means based on the temperature detected by the temperature detecting means, control is performed. Means activates the heater. And fail-safe means are connected. This fail-safe means isOne end is connected to the signal output unit of the signal output unit and the signal input unit of the control unit, the other end is connected to the second power source, and one end is a signal of the signal output unit. A pull-down resistor connected to the output unit and the signal input unit of the control unit and having the other end grounded, and a signal supplied to the control unit when the second power supply is lost is transmitted via the pull-down resistor. The target arrival signal of the grounded potentialSecure to. As a result, the control means stops the operation of the heater as described above, so that the control abnormality that erroneously operates the heater when the target temperature has already been reached is prevented.
  A pull-up resistor connected to the second power source is connected between the signal output unit of the signal output unit and the signal input unit of the control unit. Therefore, when the second power is normally supplied and the target output signal is output from the signal output unit according to the state of the control target included in the image forming unit, The target non-reaching signal having a potential based on the second power supply is supplied to the control means due to a voltage drop caused by the pull-up resistor. Accordingly, the control unit operates the control target included in the image forming unit.
  A grounded pull-down resistor is connected between the signal output unit of the signal output unit and the signal input unit of the control unit. Therefore, when the second power supply is normally supplied and the target reaching signal is output from the signal output unit according to the state of the control target included in the image forming unit, The target reaching signal having the ground potential is supplied to the control means by a pull-down resistor. Therefore, the control unit stops the operation of the control target included in the image forming unit. In this manner, the control target included in the image forming unit is controlled by the control unit.
  On the other hand, when the second power source is lost, no signal is output from the signal output means driven by the second power source. Further, the potential setting of the target unreached signal by the pull-up resistor of the potential based on the second power supply is not normally performed. However, since a pull-down resistor is connected between the signal output unit of the signal output unit and the signal input unit of the control unit, even if the second power source is lost, the signal input of the control unit The potential of the part is securely fixed to the potential of the target arrival signal which is the ground potential. As a result, the control unit stops the operation of the control target included in the image forming unit as described above, so that the control abnormality in the control target included in the image forming unit is prevented.
[0024]
[0025]
[0026]
[0027]
[0028]
  Claim7In order to solve the above-described problem, the image forming apparatus according to any one of claims 4 to 4 is provided.6In the image forming apparatus according to any one of the above, the absolute value of the first voltage is set to a value larger than the absolute value of the second voltage.
[0029]
  Claim7According to the image forming apparatus described above, since the absolute value of the first voltage is set to a value smaller than the absolute value of the second voltage, the first voltage is lost even when the second power supply is lost. When the signal output unit of the signal output unit driven by the second power source is in a high impedance state, the signal input unit of the control unit driven by the first power source is normal in the control unit. There is a possibility that a signal that can be determined as a correct signal is input. However, the fail-safe means fixes the potential of the signal input unit of the control means to a value equal to the potential of the target arrival signal when the second power supply is lost. As a result, the control unit stops the operation of the control target as described above, so that a control abnormality in the control target included in the image forming unit is prevented.
[0030]
  Claim8In order to solve the above-described problem, the image forming apparatus according to any one of claims 4 to 4 is provided.7In the image forming apparatus according to any one of the above, the detection unit is driven by the second power source.
[0031]
  Claim8According to the image forming apparatus described above, the detection unit is driven by the second power source. Therefore, when the second power source is lost, the detection means does not normally output a detection signal. However, the fail-safe means fixes the potential of the signal input unit of the control means to a value equal to the potential of the target arrival signal when the second power supply is lost. As a result, the control unit stops the operation of the control target as described above, so that the control abnormality in the control target included in the image forming unit is prevented.
[0032]
DETAILED DESCRIPTION OF THE INVENTION
  DESCRIPTION OF EXEMPLARY EMBODIMENTS Hereinafter, preferred embodiments of the invention will be described with reference to the accompanying drawings. The following description is an embodiment when the present invention is applied to a printer as an example of a printing apparatus. First, an outline of the printer in this embodiment will be described.
[0033]
  (Printer overview)
  FIG. 1 is a sectional view showing a schematic configuration of a laser beam printer 1 as an image forming apparatus to which the present invention is applied. In FIG. 1, the laser beam printer 1 includes a feeder unit that feeds paper (not shown) at the bottom of a main body case 2. The feeder unit includes a paper pressing plate 10 that is pressed by a spring (not shown), a paper feeding roller 11, and a friction separating member 14. The paper pressing plate 10 presses the paper against the paper feeding roller 11, and the paper feeding roller 11. , The uppermost sheet is separated between the sheet feeding roller 11 and the friction separating member 14 and the sheet is supplied at a predetermined timing.
  A pair of registration rollers 12 and 13 are pivotally supported on the downstream side in the paper transport direction by the rotation of the paper feed roller 11 rotating in the direction of the arrow in FIG. The sheet is conveyed at a predetermined timing to the transfer position formed by.
[0034]
  The photosensitive drum 20 is made of a positively chargeable material, for example, an organic photoreceptor whose main component is a positively chargeable polycarbonate. Specifically, the photosensitive drum 20 is a light having a predetermined thickness (for example, about 20 μm) in which a photoconductive resin is dispersed in polycarbonate on the outer periphery of a cylindrical cylindrical sleeve made of aluminum, for example. A hollow drum having a conductive layer is formed, and is pivotally supported by the main body case 2 in a state where the cylindrical sleeve is grounded. Further, the photosensitive drum 20 is rotationally driven in the direction of the arrow by a driving unit (not shown).
[0035]
  The charger 30 is composed of, for example, a positively-charged scorotron charger that generates corona discharge from a charging wire made of tungsten or the like.
[0036]
  The laser scanner unit 40 includes a laser generator (not shown) that generates a laser beam L for forming an electrostatic latent image on the photosensitive drum 20, a polygon mirror (pentahedral mirror) 41 that is driven to rotate, and a pair of It includes lenses 42 and 45 and reflecting mirrors 43, 44 and 46.
[0037]
  In the developing device cartridge 50, a toner storage chamber 52 is formed in a case 51. In the toner storage chamber 52, an agitator 53, a cleaning member 54, and a light shielding member 80 provided therebetween are provided on the rotating shaft 55. It is provided so that it can rotate freely. The toner storage chamber 52 stores toner as a positively chargeable nonmagnetic one-component developer having electrical insulation. In addition, light transmission windows 56 are provided on the side walls of the toner storage chamber 52 located on both ends of the rotation shaft 55. Further, a developing chamber 57 is formed on the photosensitive drum 20 side of the toner storage chamber 52 so as to communicate with the toner storage chamber 52 through the opening A, and the supply roller 58 and the development roller 59 are rotatably supported. . The toner on the developing roller 59 is regulated to a predetermined layer thickness by a layer thickness regulating blade 64 having a thin plate-like elasticity and used for development.
[0038]
  The transfer roller 21 is rotatably supported, and is composed of a foamed elastic body having conductivity, such as silicone rubber or urethane rubber. The transfer roller 21 is configured to reliably transfer the toner image on the photosensitive drum 20 to a sheet by an applied voltage.
[0039]
  The fixing unit 70 is provided further downstream in the sheet conveyance direction from the registration rollers 12 and 13 to the pressure contact portion between the photosensitive drum 20 and the transfer roller 21, and includes a heating roller 71 and a pressing roller 72. The toner image transferred to the paper is pressed while being heated by the heating roller 71 and the pressure roller 72 and is fixed to the paper.
[0040]
  A pair of transport rollers 73 and a paper discharge roller 74 for paper transport are provided on the downstream side in the transport direction of the fixing unit 70, and a paper discharge tray 75 is provided on the downstream side of the paper discharge rollers 74. .
[0041]
  The photosensitive drum 20, the transfer roller 21, the charger 30, and the developing device cartridge 50 described above are accommodated in the process cartridge 2a. The process cartridge 2a is detachably attached to the laser beam printer 1. ing. Further, the developing device cartridge 50 is detachably attached to the process cartridge 2a.
[0042]
  In the laser beam printer 1 of the present embodiment as described above, when the surface of the photosensitive drum 20 is uniformly charged by the charger 30, and the laser light L modulated according to the image information is emitted from the laser scanner unit 40, An electrostatic latent image is formed on the surface of the photosensitive drum 20. The electrostatic latent image is visualized with toner by the developing device cartridge 50, and the visible image formed on the photosensitive drum 20 is conveyed to the transfer position by the photosensitive drum 20. At the transfer position, the paper is supplied via the paper feed roller 11 and the registration rollers 12 and 13, and the visible image is transferred to the paper by the transfer bias applied by the transfer roller 21. The toner remaining on the photosensitive drum 20 after the transfer is collected in the developing chamber 57 by the developing roller 59.
[0043]
  Next, the sheet is conveyed to the fixing unit 70 and is nipped and conveyed by the heating roller 71 and the pressing roller 72 of the fixing unit 70, and the visible image on the sheet is pressed and heated to be fixed on the sheet. Then, the paper is discharged to a paper discharge tray 75 above the laser beam printer 1 by a pair of transport rollers 73 and paper discharge rollers 74, and the image forming operation is completed.
[0044]
  (Configuration of control unit)
  Next, the configuration of the control unit in the laser beam printer 1 of the present embodiment will be described in detail.
[0045]
  FIG. 2 is a block diagram showing the configuration of the control unit. As shown in FIG. 2, the control unit includes a main circuit board 90, a low voltage power supply board 93, a high voltage power supply board 95, and an engine circuit board 96.
[0046]
  The main board 90 includes a parallel interface connector 91 and a USB connector 92 for connection with a computer or the like, a CPU and a memory (not shown), a connector P9 for connection with a low-voltage power supply unit 93 in the control unit, A connector P4 for connection to the engine circuit board 96 and a connector P10 for connection to the laser element 105 of the laser unit 40 are provided. With such a configuration, the main board 90 controls the operation of the entire control unit.
[0047]
  The low voltage power supply board 93 includes a power switch 94, a connector CN1 for connection with the halogen lamp 102 of the fixing unit 70, a connector CN101 for connection with the engine circuit board 96 in the control unit, and a low voltage power supply circuit (not shown). It has.
[0048]
  The low-voltage power supply circuit generates 3.3V used as a power source for a CPU or a memory, 5V used for driving a small motor 104, and 24V used as a power source for a DC motor 98, a solenoid 99, etc. It is a circuit to make. As will be described later, 5V is also used as a driving power source for a comparator as a comparison means.
[0049]
  The high-voltage power circuit board 95 includes a connector CN2 for connection to the engine circuit board 96 in the control unit, and a high-voltage power circuit (not shown). The high voltage power supply circuit is a circuit that generates a high voltage of 3 kV for generating a voltage supplied to the charger 30 and a voltage supplied to the photosensitive drum 20 and the developing roller 59.
[0050]
  The engine circuit board 96 is connected to a connector P7 for connection to the fan 97, a connector P8 for connection to the DC motor 98, and a small motor 104 for rotating the polygon mirror 41 of the laser unit 40. Connector P12 for connection, connector P13 for connection with solenoid 99, connector P14 for connection with panel unit 100 including switch 101 and the like, connector P5 for connection with low voltage power supply board 93 , P15, a connector P3 for connection to the main board 90, a connector P2 for connection to the high voltage power supply board 95, an ASIC (not shown) (shown as ASIC 130 in FIG. 4), and the like. The DC motor 98 is a motor generally called a main motor, and is a rotational drive source such as the photosensitive drum 20, the developing roller 59, the heating roller 71, the transfer roller 21, and the conveying roller 73. In other words, the engine circuit board 96 controls the rotational drive of the main roller body related to the image forming operation by controlling the DC motor 98. The engine circuit board 96 uses the high-voltage power supply board 95 to control supply of high-voltage power necessary for the image forming operation. Further, the engine circuit board 96 is a heating roller based on drive control of the small motor 104, solenoid 99, and fan 97 of the laser unit 40, control of key input and display on the panel unit 100, and temperature detection by the thermistor 103. 71 temperature control is performed.
[0051]
  (Configuration of temperature control circuit)
  In the present embodiment, a temperature control circuit is provided on the main board 90. Hereinafter, the configuration of the temperature control circuit will be described with reference to FIG.
[0052]
  As shown in FIG. 3, the temperature control circuit of this embodiment includes a CPU 200, a control unit 201, a fail safe circuit 202, a temperature comparison unit 203, a temperature detection unit 204, an abnormally high temperature detection unit 205, A high temperature forced OFF control unit 206 and a heater 207 are provided.
[0053]
  The CPU 200 is means for controlling the entire apparatus, and is driven by a first power supply (not shown) that supplies a voltage of 3.3 V as a first voltage value.
[0054]
  A control unit 201 serving as a control unit is a unit that controls on / off of the heater 207 based on a signal from the temperature comparison unit 203, and includes an ASIC or the like. The control unit 201 is driven by a first power source (not shown) that supplies a voltage of 3.3 V as a first voltage value.
[0055]
  A fail safe circuit 202 as fail safe means includes a pull-up resistor as a target unreached signal potential setting unit connected to a 5 V power source as a second power source (not shown) for supplying a voltage of 5 V as a second voltage value. R1 and a pull-down resistor R2 as a grounded target arrival signal potential setting unit. The pull-up resistor R1 and the pull-down resistor R2 are connected to a signal line connecting the signal output terminal of the temperature comparison unit 203 and the signal input terminal of the control unit 201.
[0056]
  The temperature comparison unit 203 serving as a signal output unit includes an open collector or open drain type comparator CMP1, a target voltage based on a temperature control signal output from the control unit 201 as a signal corresponding to the target temperature, and a temperature detection unit. A means for comparing the detection voltage based on the detection signal output from 204 and outputting a signal according to the comparison result. When the detected voltage is higher than the target voltage, that is, when the detected temperature is equal to or higher than the target temperature, the temperature comparison unit 203 outputs an L (Low) level signal as the target arrival signal. Further, when the detected voltage is lower than the target voltage, that is, when the detected temperature is lower than the target temperature, an H (High) level signal is output as the target unreached signal.
[0057]
  Here, the temperature comparison unit 203 is connected to a 5V power source as a second power source (not shown) that supplies a voltage of 5V as the second voltage value, and the drive voltage is set to 5V. This is because the comparator CMP1 requires a voltage obtained by subtracting 1.5 V from the drive voltage as the dynamic range.
[0058]
  The temperature detection unit 204 as temperature detection means is provided so as to come into contact with the heating roller 71 of the fixing unit 70 and includes a thermistor or the like.
[0059]
  The abnormal high temperature detection unit 205 includes a comparator CMP2, resistors R3, R4, R5, and a capacitor C1. When the voltage based on the signal output from the temperature detection unit 204 exceeds a predetermined reference voltage, the abnormal high temperature detection unit 205 generates an abnormal high temperature. This circuit detects and outputs a predetermined abnormality signal to the control unit 201 and the abnormally high temperature forced OFF control unit 206. The drive voltage of the abnormal high temperature detector 205 is also set to 5V. When the abnormal high temperature is detected, the heater 207 is turned off on the hardware circuit, and the heater 207 is also turned off on the software control program of the CPU 200 via the control unit 201. Further, the control program of the CPU 200 includes a program for determining that a failure has occurred and turning off the heater 207 when a target non-reaching signal is input even if the heater is heated for a predetermined time.
[0060]
  The abnormally high temperature forced OFF control unit 206 includes a comparator CMP3 and resistors R6 and R7. When the abnormal time signal is output from the abnormally high temperature detection unit 205, the hardware circuit is forcedly applied to the heater 207. An OFF signal is output above. The drive voltage of the forced OFF control unit 206 at abnormally high temperatures is also set to 5V. Thereby, the current supply to the heater 207 is stopped. The abnormally high temperature forced OFF control unit 206 is provided for impedance adjustment between the abnormally high temperature detection unit 205 and the heater 207, and is not essential. That is, the output of the abnormal high temperature detection unit 205 may be directly input to the heater 207.
[0061]
  In the temperature control circuit as described above, when an H level target non-reaching signal is output from the temperature comparison unit 203 to the control unit 201, the control unit 201 turns on the heater 201 and sets the temperature of the heating roller 71. Raise. On the other hand, when an L level target reaching signal is output from the temperature comparison unit 203 to the control unit 201, the control unit 201 turns off the heater 201 and lowers the temperature of the heating roller 71. By such control, the temperature of the heating roller 71 is maintained at the target temperature.
[0062]
  Here, a case where a disconnection or the like occurs and a 5 V power supply abnormality occurs will be described. It is assumed that 3.3V power is continuously supplied to the control unit 201. In this case, since the supply of 5 V power to the open collector or open drain type comparator CMP1 of the temperature comparison unit 203 is stopped, the output of the temperature comparison unit 203 is in a high impedance state. Also, the abnormal high temperature detector 205 becomes inoperable.
[0063]
  Also in the fail safe circuit 202, since the supply of 5V power is stopped, an L level signal, that is, a target reaching signal is output to the control unit 201 by the pull-down resistor R2. That is, in the control program of the CPU 200, the target attainment signal is output without determining whether or not the time during which both the signal for instructing the heater heating and the target unreached signal are generated exceeds the predetermined time. Is done.
[0064]
  Therefore, the control unit 201 immediately turns off the heater 201 and lowers the temperature of the heating roller 71. As described above, when a 5V power supply abnormality occurs, power is not supplied to the temperature comparison unit 203 and normal temperature detection is not performed. However, as described above, the heater 201 is always in an off state. The temperature of the heating roller 71 does not become higher than a predetermined temperature.
[0065]
  On the other hand, in the conventional apparatus, since the fail-safe circuit as in the present embodiment is not provided, when a 5V power supply abnormality occurs, a pull-up resistor connected to the 3.3V power supply is used. As a result, an H level target non-reaching signal is output to the control unit 201, the heater 201 is not turned off, and the temperature of the heating roller 71 may be higher than a predetermined temperature.
[0066]
  Therefore, the apparatus of the present embodiment can provide a safer apparatus than the conventional apparatus with an extremely simple and inexpensive configuration.
[0067]
  In addition, according to the configuration as described above, an L level signal is always input to the control unit 201 regardless of the on / off control, so that the control unit 201 can detect the occurrence of an abnormality. is there. That is, even if the heater is turned on for a predetermined time, it is possible to determine that it is abnormal when the target non-reaching signal is input.
[0068]
  In the above-described embodiment, the example in which the fail-safe circuit of the present invention is provided in the temperature control circuit has been described. However, the present invention is not limited to such a configuration. For example, the presence or absence of toner is detected. It can also be applied to circuits.
  Note that when the 3.3V power supply is lost, the entire control system stops, so that no device failure occurs.
[0069]
  Furthermore, in the embodiment described above, an example of a circuit in which 5V and 3.3V are mixed has been described. However, the present invention is not limited to such a configuration, and other than this, 2.5V, 12V , 24V, etc. can be applied to a mixed circuit.
[0070]
  The present invention has been described above based on the embodiments. However, the present invention is not limited to the above embodiments, and various improvements and modifications can be made without departing from the spirit of the present invention.
[0071]
【The invention's effect】
  According to the fail-safe circuit of the first aspect, when the second power source is lost, the signal grounded via the pull-down resistor is supplied as the input signal to the control means, so that the control of the control target by the control means is stopped. As a result, it is possible to prevent the control abnormality by the control means with a simple configuration at low cost and with certainty.
[0072]
  According to the fail safe circuit of the second aspect, since the signal output means is means for comparing signals, it is necessary to ensure a wider operating range than other means. Therefore, the absolute value of the second voltage value in the second power source that drives the signal output means is set to a value larger than the absolute value of the first voltage value of the first power source. As a result, when the signal output unit of the signal output means driven by the second power supply is in a high impedance state when the second power supply is lost, the second power supply is driven by the first power supply. There is a possibility that a signal that can be determined as the on-potential signal in the control means is input to the signal input section of the control means. Further, since the control means is a means for controlling the control target based on the input signal from the signal output means, when a signal that can be determined as the on-potential signal is input, the control amount of the control target is set. Even when it is not necessary to increase the control means, it is conceivable that the control means increases the control amount of the control target. However, the fail-safe circuit of the present invention inputs a ground potential via a pull-down resistor to the signal input unit of the control means when the second power supply is lost. As a result, the control unit stops the control of the control target as described above, and thus it is possible to prevent a control abnormality in the control target.
[0073]
  According to the fail-safe circuit of claim 3, when the second power supply is lost, a signal in a high impedance state is output from the signal output means regardless of the temperature signal. Since the control means is supplied with a ground potential signal grounded via the pull-down resistor, the control means controls the temperature of the heating device not to increase. As a result, it is possible to prevent a control abnormality that erroneously operates the heater when the target temperature has already been reached.
[0074]
  According to the image forming apparatus of the present invention, when the second power source is lost, the potential of the signal input unit of the control unit is fixed to the ground potential equal to the potential of the target arrival signal. Control abnormality for the target can be prevented with a simple configuration at low cost and with certainty.When the second power supply is lost because a pull-up resistor connected to the second power supply is connected between the signal output section of the signal output means and the signal input section of the control means. In this case, no signal is output from the signal output means driven by the second power supply, and the potential of the target unreached signal is set normally by the pull-up resistor of the potential based on the second power supply. It will not be broken. However, since a pull-down resistor is connected between the signal output unit of the signal output unit and the signal input unit of the control unit, even if the second power source is lost, the signal input of the control unit The potential of the part is securely fixed to the potential of the target arrival signal which is the ground potential. As a result, since the control unit stops the operation of the control target included in the image forming unit as described above, the control abnormality in the control target included in the image forming unit can be reliably prevented with a simple configuration. Can do.
[0075]
  According to the image forming apparatus of the fifth aspect, when the state of the control target detected by the detection unit has reached the target value, the target arrival signal is supplied from the signal output unit to the control unit, and the control unit Stops the operation of the controlled object included in the image forming means. When the second power supply is lost, the potential of the signal input unit of the control means is fixed to a value equal to the potential of the target arrival signal by the fail safe means. As a result, since the control unit stops the operation of the control target included in the image forming unit, the control target that has already reached the target value is surely prevented from malfunctioning that erroneously reaches the target value. be able to.
[0076]
  According to the image forming apparatus of the sixth aspect, when the target arrival signal indicating that the fixing device has reached the target temperature is supplied, the control unit stops the operation of the heater of the fixing device. The fail-safe means fixes the potential of the signal input unit of the control means to a value equal to the potential of the target arrival signal when the second power supply is lost. As a result, since the control means stops the operation of the heater, it is possible to reliably prevent a control abnormality that erroneously operates the heater when the target temperature has already been reached.When the second power supply is lost because a pull-up resistor connected to the second power supply is connected between the signal output section of the signal output means and the signal input section of the control means. In this case, no signal is output from the signal output means driven by the second power supply, and the potential of the target unreached signal is set normally by the pull-up resistor of the potential based on the second power supply. It will not be broken. However, there is a pull-down resistor between the signal output unit of the signal output unit and the signal input unit of the control unit. Therefore, even when the second power supply is lost, the potential of the signal input unit of the control means is reliably fixed to the potential of the target arrival signal that is the ground potential. As a result, since the control unit stops the operation of the control target included in the image forming unit as described above, the control abnormality in the control target included in the image forming unit can be reliably prevented with a simple configuration. Can do.
[0077]
[0078]
  Claim7According to the image forming apparatus described above, since the absolute value of the first voltage is set to a value smaller than the absolute value of the second voltage, the first voltage is lost even when the second power supply is lost. When the signal output unit of the signal output unit driven by the second power source is in a high impedance state, the signal input unit of the control unit driven by the first power source is normal in the control unit. There is a possibility that a signal that can be determined as a correct signal is input. However, the fail-safe means fixes the potential of the signal input unit of the control means to a value equal to the potential of the target arrival signal when the second power supply is lost. As a result, since the control unit stops the operation of the control target as described above, it is possible to reliably prevent the control abnormality in the control target included in the image forming unit.
[0079]
  Claim8According to the image forming apparatus described above, the detection unit is driven by the second power source. Therefore, when the second power source is lost, the detection means does not normally output a detection signal. However, the fail-safe means fixes the potential of the signal input unit of the control means to a value equal to the potential of the target arrival signal when the second power supply is lost. As a result, since the control unit stops the operation of the control target as described above, it is possible to reliably prevent the control abnormality in the control target included in the image forming unit.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view illustrating a schematic configuration of a printing apparatus according to an embodiment of the present invention.
FIG. 2 is a block diagram illustrating a schematic configuration of a control unit in the printing apparatus of FIG. 1;
3 is a block diagram showing a schematic configuration of a temperature control circuit in the control unit of FIG. 2;
[Explanation of symbols]
  1 Laser beam printer
  70 Fixing unit
  71 Heating roller
  201 Control unit
  202 Fail-safe circuit
  203 Temperature comparison unit
  204 Temperature detector

Claims (8)

A control unit that is driven by a first power source having a first voltage value and controls a control target so as to increase a control amount when an input signal is an on-potential that is distinguished from a ground potential;
A signal output unit that is driven by a second power source having a second voltage value different from the first voltage value and outputs a signal corresponding to the state of the control target to the control unit as the input signal;
A pull-up resistor having one end connected to the signal output unit of the signal output unit and the signal input unit of the control unit and the other end connected to the second power source;
A pull-down resistor having one end connected to the signal output unit of the signal output unit and the signal input unit of the control unit and the other end grounded;
When the second power supply is lost, a signal grounded via the pull-down resistor is supplied to the control unit as the input signal, and the control of the control target by the control unit is stopped.
A fail-safe circuit characterized by that.   2. The fail-safe circuit according to claim 1, wherein the signal output means is means for comparing signals, and the control means is means for controlling an object to be controlled based on an input signal from the signal output means. .   The signal output means compares a temperature signal based on the temperature of the heating device as a control target with a reference signal based on a target temperature, and when the temperature corresponding to the temperature signal is lower than the target temperature, the ground potential and A means for outputting a distinguished on-potential signal, wherein the control means is a means for controlling the temperature of the heating device to rise when the input signal from the signal output means is an on-potential. The fail-safe circuit according to claim 2. An image forming means for forming an image on a recording medium;
A first power supply for supplying a first voltage value;
When the target attainment signal that is driven by the first power supply and indicates that the target state of the controlled object is supplied is supplied, the operation of the controlled object is stopped, and the target not reached signal that indicates that the target state of the controlled object has not been reached is supplied Control means for actuating the control object when it is
A second power supply for supplying a second voltage value different from the first voltage value;
Signal output means that is driven by the second power source and supplies the target reaching signal or the target unreached signal to the control means according to the state of the control target;
One end is connected to the signal output unit of the signal output unit and the signal input unit of the control unit, the other end is connected to the second power source, and one end is a signal of the signal output unit. A pull-down resistor connected to the output unit and the signal input unit of the control unit and having the other end grounded, and a signal supplied to the control unit when the second power supply is lost is transmitted via the pull-down resistor. Fail-safe means for fixing to the target arrival signal at a grounded potential ;
An image forming apparatus comprising:   Detection means for detecting a state of the control target and supplying a detection signal is further provided, wherein the signal output means is configured to detect the target arrival signal or the target unreachable based on the detection signal and a signal corresponding to the target value of the control target. The image forming apparatus according to claim 4, wherein a signal is supplied. The image forming unit includes a fixing device that heats and fixes a developer image on a recording material with a heater,
As the detection means, provided with a temperature detection means for detecting the temperature of the fixing device,
The control means sets the heater as the control target, stops the operation of the heater when the target arrival signal indicating that the temperature in the fixing device has reached the target temperature is supplied, and sets the temperature in the fixing device. Is a means for operating the heater when the target non-reaching signal indicating that the target temperature has not been reached is supplied,
Said fail-safe means, one end is connected to the signal input of the control means and the signal output of the signal output means, a pull-up resistor the other end of which is connected to said second power supply,
A pull-down resistor having one end connected to the signal output unit of the signal output unit and the signal input unit of the control unit and the other end grounded is supplied to the control unit when the second power supply is lost A means for fixing a signal to the target arrival signal at a potential grounded via the pull-down resistor ;
The image forming apparatus according to claim 5. The image forming apparatus according to claim 4, wherein the absolute value of the first voltage is set to be smaller than the absolute value of the second voltage . The image forming apparatus according to claim 4, wherein the detection unit is driven by the second power source .

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