JP2013025055A - Image forming apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce standby power consumption while maintaining noise reduction property without changing capacity of a capacitor that is disconnectably connected to a commercial power supply.SOLUTION: An image forming apparatus (1) includes: a capacitor (731) that is disconnectably connected in parallel to both ends of a commercial power supply (8); and a heater (43) that is heated with AC power supplied from the commercial power supply and the capacitor. When the AC power supplied from the commercial power supply is cut off, residual charge remains in the capacitor is discharged to the heater.

Description

  The present invention relates to an image forming apparatus, and more particularly, to an image forming apparatus that reduces residual charges accumulated in a noise removing capacitor connected in parallel to a commercial power supply after a power switch is turned off.

In general, an electronic device connected to a commercial power supply has an AC line filter built in as a noise countermeasure. In this AC line filter, a so-called X capacitor is connected between the lines as a countermeasure for the normal mode. The X capacitor generally has a large value of about 1 [μF], and a general AC line filter has a discharge resistor connected in parallel to the X capacitor.
While the discharge resistor connected in parallel with the capacitor increases the standby power, if the capacitance of the capacitor is 0.1 μF or less, the standby power can be lowered because the discharge resistor is unnecessary.

JP 2008-160953 A

  Electronic devices, particularly image forming apparatuses, have a fixing device with high power consumption, but may be operated in an energy saving mode in which image formation is not performed. In this energy saving mode, it is preferable to reduce standby power. Therefore, it is conceivable to use a method of reducing standby power using a capacitor having a capacitance of 0.1 [μF] or less. However, the method using a capacitor of 0.1 [μF] or less has a problem that the capacity of the capacitor is too small, the cutoff frequency becomes high, and the characteristics as an AC line filter cannot be satisfied.

  The present invention has been made to solve the above-described problems, and reduces standby power while maintaining noise elimination characteristics without changing the capacity of a capacitor that is detachably connected to a commercial power source. It is an object of the present invention to provide an image forming apparatus capable of performing the above.

  In order to solve the above problems, an image forming apparatus of the present invention includes a capacitor that is detachably connected in parallel with both ends of a commercial power source, and a heater that heats the commercial power source and AC power supplied from the capacitor. In the image forming apparatus provided, when the AC power supplied from the commercial power source is cut off, the residual charge remaining in the capacitor is discharged to the heater.

  According to the present invention, standby power can be reduced while maintaining noise elimination characteristics without changing the capacity of a capacitor that is detachably connected to a commercial power source.

1 is an overall configuration diagram of an image forming apparatus of the present invention. It is a perspective view of a fixing unit. It is a block diagram which shows the control processing which the control part of this invention performs. It is a block diagram of the power supply part for a heating of this invention, and its peripheral device. (A) AC voltage of commercial power supply, (b) timing at which zero cross signal is output, (c) temperature data detected by temperature detection sensor, (d) heater control signal output by control unit, (e) X capacitor of It is a figure which shows energy and each in time series. It is a flowchart which shows the control processing which a control part performs. It is a block diagram of the modification of the heater switch circuit which is a part of the power supply part for a heating of this invention.

<< First Embodiment >>
The image forming apparatus of the present invention will be described with reference to FIG.
The image forming apparatus 1 includes a paper feeding unit 2 that supplies paper 20, an image forming unit 3 that forms a toner image (image) on the paper 20, a fixing unit 4 that fixes a toner image on the paper 20, and a paper feeding unit. 2, a sheet transport unit 5 that discharges the sheet 20 to the outside via the image forming unit 3 and the fixing unit 4, a control unit 6 (FIG. 3) that controls each component unit, and each component unit And a power supply unit 7 (FIG. 3) for applying a voltage necessary for operation. An AC voltage is applied to the power supply unit 7 from a commercial power supply 8 (FIG. 3). Further, the image forming apparatus 1 includes a power switch 71 (FIG. 3), is connected to the commercial power supply 8 by a cable with an AC plug, and is supplied with AC power by turning on the power switch 71.

(Paper Feeder 2)
The paper feed unit 2 includes a paper cassette 21 and a pickup roller 22.
The paper cassette 21 stores one or a plurality of papers 20. Cassettes stored depending on the type and size of the paper 20 are provided separately.
The pickup roller 22 is rotatably connected to an actuator (not shown) such as a motor, and is rotated by being controlled by the control unit 6 to supply one sheet 20 from the sheet cassette 21 to the sheet transport unit 5.

(Image forming unit 3)
The image forming unit 3 includes four developing devices 31 (31K, 31Y, 31M, 31C), four LED heads 32 (32K, 32Y, 32M, 32C), and four transfer rollers 33 (33a, 33b, 33c, 33d). K, Y, M, and C are characters representing colors, and correspond to black, yellow, magenta, and cyan, respectively.
In the developing device 31, four color developing devices 31 (31K, 31Y, 31M, 31C) filled with toner are arranged along the conveyance direction (arrow) of the paper 20, and each developing device is exposed. The electrostatic latent image formed by the above is developed to form a toner image. Details of the developing device 31 will be described later.
The LED head 32 is formed by arranging a plurality of single crystal thin film light emitting elements on a line, and exposes a photosensitive drum 315 (provided in the developing device 31) described later in accordance with print data from the control unit 6 to electrostatically A latent image is formed.
The transfer roller 33 is a roller for transferring a toner image formed on a developing roller 313 (provided in the developing device 31) described later to the paper 20.

(Developing device 31)
The developing device 31 includes a toner cartridge 311, a toner supply roller 312, a developing roller 313, a charging roller 314, and a photosensitive drum 315.
The toner cartridge 311 is filled with toner as a developer.
The toner supply roller 312 is a roller for supplying toner from the toner cartridge 311 to the developing roller 313.
The developing roller 313 is a roller that supplies toner to the photosensitive drum 315, and the toner moves from the developing roller 313 to the electrostatic latent image formed on the photosensitive drum 315 by the action of an electric field. Toner is being supplied.
The charging roller 314 is a roller that uniformly charges the surface of the photosensitive drum 315 to the negative electrode.
The photosensitive drum 315 is irradiated with light from the LED head 32, and the surface layer charged on the negative electrode is discharged to form an electrostatic latent image. The photosensitive drum 315 is supplied with toner by the developing roller 313 and is developed by attaching the toner to the electrostatic latent image to form a toner image.

(Fixing unit 4)
The fixing unit 4 includes fixing rollers 41 a and 41 b and a temperature detection sensor 42.
The fixing roller 41a includes a heater 43 therein, and the heater 43 heats the surface of the fixing roller 41a to a predetermined fixing temperature. The heater 43 is, for example, a halogen heater. Details of the configuration of the heater 43 will be described later.
The operation of each component of the fixing unit 4 will be described with reference to FIG. A sheet 20 is conveyed in the direction of the arrow by a sheet conveying unit 5 described later. When the fixing roller 41a and the fixing roller 41a rotate so that the paper 20 moves in the transport direction, the paper 20 is sandwiched between two rollers, the fixing rollers 41a and 41b, and is pressed from the front and back surfaces. . As a result, the toner image is fixed on the paper 20.
The temperature detection sensor 42 detects the surface temperature of the fixing roller 41 a and outputs temperature data to the control unit 6. The temperature detection sensor 42 is, for example, a thermistor.

Returning again to FIG.
(Paper transport section 5)
The paper transport unit 5 transports the paper 20 along a transport path 50 (indicated by a thick line) and discharges the paper 20 to the outside from the paper feed unit 2 via the image forming unit 3 and the fixing unit 4. The paper transport unit 5 includes rollers such as registration rollers 51 (51a and 51b), a transfer belt 52, and a discharge roller 53.
The registration rollers 51 (51 a, 51 b) are rollers that are installed before the paper 20 conveyed from the paper supply unit 2 reaches the image forming unit 3 and adjusts the direction of the paper 20.
The transfer belt 52 is a belt member formed in an endless shape, and is a belt that conveys the paper 20 whose orientation is adjusted by the registration roller 51 to the fixing unit 4. The drive rollers 52a and 52b are conveying means for rotating the transfer belt 52, and also function as cooling means for cooling the transfer belt 52 warmed by the fixing unit 4.
The discharge roller 53 discharges the sheet 20 (the toner image fixed by the fixing unit 4) conveyed via the fixing unit 4 to the outside of the image forming apparatus 1.

(Control unit 6)
The control unit 6 is, for example, a control unit configured by a CPU (Central Processing Unit), acquires a program stored in a storage unit 93 to be described later, and stores data in the storage unit 93 or stores the data in the storage unit 93. Data is acquired from the image forming unit 1 to control each component included in the image forming apparatus 1.
The storage unit 93 is a storage unit configured by a ROM (Read Only Memory) 931, a RAM (Random Access Memory) 932, an HD (Hard Disk), an optical disk, or the like.

In the present embodiment, a control process executed by the control unit 6 for each component included in the image forming apparatus 1 will be described with reference to FIG. The thick line in FIG. 3 indicates that the voltage from the commercial power source 8 is applied. In the AC-DC conversion unit 74, the AC zero cross circuit 75, and the heater switch circuit 76, the power switch 71 included in the power source unit 7 is off. When an AC voltage is applied. An AC voltage is applied to the heater 43 when the heater switch circuit 76 is on. A DC voltage converted from an AC voltage by an AC-DC converter 74 (described later) is applied to the controller 6. Although not shown, the AC-DC conversion unit 74 includes an actuator control unit 92 to be described later, an actuator such as a motor (not shown) controlled by the actuator control unit 92, and the image forming apparatus 1 such as the image forming unit 3. A DC voltage is applied to each component provided.
Here, the AC-DC converter 74 includes a power storage unit (capacitor) (not shown) inside, and generates an output voltage only for a so-called output voltage holding time even after the power switch 71 is switched off. Can do. For this reason, the control part 6 can complete | finish a process normally.

The control unit 6 receives a zero cross signal from an AC zero cross circuit 75 (described later) at a timing (zero cross point) at which the instantaneous value of the AC voltage of the commercial power supply 8 becomes zero. Details will be described later.
The controller 6 outputs ON / OFF of the heater control signal to the heater switch circuit 76 as soon as a zero cross signal is received from the AC zero cross circuit 75 (described later). Thereby, the heater switch circuit 76 can be synchronized with the zero cross signal output from the AC zero cross circuit 75. The heater switch circuit 76 is a switch that connects the commercial power supply 8 and the heater 43 and applies an AC voltage to the heater 43. The heater switch circuit 76 is turned on / off in response to a heater control signal from the control unit 6. Switch off (OFF). In this way, the control unit 6 outputs a heater control signal (ON / OFF signal) to control application / interruption of the AC voltage to the heater 43. Details of the control processing performed by the control unit 6 will be described later. In the present embodiment, the heat control signal is ON when the control unit 6 is outputting a heat control signal, and the heat control signal is OFF when the control unit 6 is not outputting a heat control signal. It is.

  The control unit 6 acquires temperature data from the temperature detection sensor 42, and outputs a heater control signal based on the temperature data. For example, the control unit 6 controls the output (ON / OFF) of the heater control signal and the phase angle of the phase control so that the temperature data is within a predetermined range. Thereby, the surface temperature of the fixing roller 41a is maintained at a temperature within a predetermined temperature range. Details will be described later.

  The control unit 6 is connected to a communication unit 91 connected to a network N such as a LAN (Local Area Network), acquires print data transmitted from a computer connected to the end of the network N, and stores the print data in the print data. Based on this, each component of the image forming apparatus 1 is controlled to print on the paper 20.

The control unit 6 outputs an instruction signal to the actuator control unit 92, and controls the motor, the clutch, and the air cooling fan via the actuator control unit 92. The various rollers included in the CPU are rotated by a motor, the fan is rotated, and the CPU is cooled.
The control unit 6 acquires time data from the timer 94 and calculates an elapsed time.
The control unit 6 includes various sensors provided in the image forming apparatus 1 (such as a paper travel path sensor for detecting a paper position and a sensor for correcting image density / color misregistration), each component provided in the image forming unit 3, and It controls on / off of a switch connecting the AC-DC converter 74. This control is processing for the purpose of reducing power consumption consumed by the image forming apparatus 1.

(Power supply unit 7)
The power supply unit 7 is connected to an external commercial power supply 8, and includes a power switch 71, a protection element 72, a power noise filter 73, an AC-DC conversion unit 74, and an AC zero-cross circuit 75 (heating power supply unit 10). And a heater switch circuit 76 (heating power supply unit 10).
In the power supply unit 7, the heater switch circuit 76 supplies AC power from the commercial power supply 8 to the heater 43 of the fixing unit 4, and the AC-DC conversion unit 74 converts the AC voltage into a predetermined DC voltage, and other images. It applies to each component with which the forming apparatus 1 is provided. Further, the power supply unit 7 detects a zero cross point where the AC zero cross circuit 75 has an instantaneous value of AC voltage of 0, and outputs a zero cross signal to the control unit 6.
The power noise filter 73 is a circuit that reduces the passage of noise. Details will be described later.
The AC-DC converter 74 converts the applied AC voltage into a DC voltage and generates a DC voltage having a predetermined value by performing step-down. The AC-DC converter 74 of this embodiment generates +24 [V], +5 [V], +3.3 [V], and a zero level voltage (0 [V]).

The AC zero-cross circuit 75 detects a zero-cross point where the instantaneous value of the AC voltage is 0 and outputs a zero-cross signal to the control unit 6. Details will be described later.
The heater switch circuit 76 is a switch circuit that supplies AC power to the heater 43, and switches the switch on (ON) / off (OFF) or performs phase control in accordance with a heater control signal from the control unit 6. Or Details will be described later.

  The protection element 72 shown in FIG. 4 prevents a large current from flowing into the image forming apparatus 1 when an abnormal high voltage generated due to lightning is applied. For example, the protection element 72 includes a varistor or the like. .

(Power noise filter 73)
The power noise filter 73 includes an X capacitor 731, a common mode choke coil 732, two Y capacitors 733 and 734, input terminals a and b, and output terminals c and d. The common mode choke coil 732 is configured by winding a first winding and a second winding in the same direction around a single magnetic core. In the power noise filter 73, the input terminal a and the output terminal c are connected to each other by the first winding, and the input terminal b and the output terminal d are connected to each other by the second winding. Further, the power noise filter 73 has an X capacitor 731 connected between the input terminal a and the input terminal b, and a Y capacitor 733 connected between the output terminal c and a ground terminal FG (Frame Ground). A Y capacitor 734 is connected between the terminal d and the ground terminal FG.

  Here, for the X capacitor 731, for example, a capacitor of 1 [μF] is used in order to obtain necessary filter characteristics. For the Y capacitors 733 and 734, for example, those of 4700 [pF] are used. The X capacitor 731 is for reducing normal mode noise, and the common mode choke coil 732 and the Y capacitor 733 are for reducing common mode noise.

  In the conventional power noise filter, a discharge resistor is connected in parallel with the X capacitor 731. This discharge resistor is a resistor for consuming residual charge accumulated in the X capacitor 731. However, even when the power switch 71 is on, an alternating current flows through the discharge resistor and power is consumed. In the present embodiment, the residual charge accumulated in the X capacitor 731 is consumed when the AC plug is removed or the power switch 71 is turned off by the user without connecting the discharge resistor. Further, the heater switch circuit 76 and the heater 43 are connected.

(AC zero cross circuit 75)
The AC zero-cross circuit 75 (heating power supply unit 10) includes a transformer 751, a rectifier circuit 752, a photocoupler 753, and a Schmitt trigger 754.

The transformer 751 steps down the alternating voltage applied to the primary side and outputs the alternating voltage to the secondary side.
The rectifier circuit 752 is a bridge-type full-wave rectifier circuit composed of four diodes, rectifies the waveform of the AC voltage applied from the input terminals AC1 and AC2, and outputs the output terminals DC1 (+) and DC2 (−). Output from. In the positive half cycle, the current flows from the input terminal AC1 through the output terminal DC1 (+), and flows from the output terminal DC2 (−) to the input terminal AC2 through the resistor and the photocoupler 753. In the negative half cycle, the current flows from the input terminal AC1 through the output terminal DC2 (−), and flows from the output terminal DC1 (+) to the input terminal AC2 through the photocoupler 753 and the resistor.

The photocoupler 753 includes a light emitting diode 7531 (light emitting element) and a phototransistor 7532 (light receiving element). The phototransistor 7532 receives light emitted from the light emitting diode 7531 so that a current flows between the collector and the emitter. become. Here, when the voltage between both ends of the light emitting diode 7531 becomes less than the forward voltage (for example, 0.7 [V]), the light emitting diode 7531 does not emit light until the voltage between the both ends becomes the forward voltage of the light emitting diode 7531 next time. During this time, no current flows between the collector and emitter of the phototransistor 7532.
The phototransistor 7532 has a collector pulled up via a resistor.
When a current flows between the collector and the emitter, the collector potential becomes a low level, and when no current flows, the collector potential becomes a high level.
The Schmitt trigger 754 functions as a buffer. However, once the output level changes, the Schmitt trigger 754 is configured so that the output level does not change with respect to a slight change in input voltage.
Therefore, in the AC zero-cross circuit 75, the AC voltage applied to the primary side of the transformer 751 emits light in the positive half cycle and the negative half cycle, and the light emitting diode 7531 emits light, and the collector potential of the phototransistor 7532 becomes low level. Since the voltage across the light emitting diode 7531 becomes less than the forward voltage at the zero crossing point of the AC voltage, the light emitting diode 7531 does not emit light, and the collector potential of the phototransistor 7532 becomes high level. That is, the AC zero cross circuit 75 outputs a zero cross signal that becomes a high level at the zero cross point.

The circuit configuration of the AC zero cross circuit 75 in the present embodiment will be described.
The primary side of the transformer 751 is connected to the input terminals a and b of the power noise filter 73, and the secondary side is connected to the input terminals AC1 and AC2 of the rectifier circuit 752. Output terminals DC1 (+) and DC2 (−) of the rectifier circuit 752 are connected to the photocoupler 753.
The light-emitting diode 7531 of the photocoupler 753 has a cathode connected to the output terminal DC1 (+) of the rectifier circuit 752 via a resistor, and an anode connected to DC2 (−). In the phototransistor 7532, a base serving as a light receiving unit is disposed in a direction to receive light from the light emitting diode 7531, a collector is connected to a +5 [V] DC power source via a resistor, and an emitter is grounded.
The Schmitt trigger 754 has an input terminal connected to a +5 [V] DC power supply via a resistor, and an output terminal connected to the control unit 6. Here, the DC power source of +5 [V] is the AC-DC converter 74.

  As described above, the AC voltage applied to the AC zero cross circuit 75 from the input terminals a and b of the power noise filter 73 is rectified by the rectifier circuit 752 and becomes 0 [V] every half cycle (0.7 [V] ] Less than). At this timing, the light emitting diode 7531 is turned off, the emitter-collector of the transistor 7532 is cut off, the input potential of the Schmitt trigger 754 becomes high, and the Schmitt trigger 754 outputs a zero cross signal to the control unit 6. Thereby, the control unit 6 can detect the zero cross point of the commercial power supply 8.

(Heater 43)
Here, the configuration of the heater 43 will be described.
The heater 43 includes a halogen lamp 431, a thermostat 432, and terminals p and q. The terminal p, the thermostat 432, the halogen lamp 431, and the terminal q are connected in series in this order.
The halogen lamp 431 converts input power into heat when an AC voltage is applied between the terminals p-q. Thereby, the fixing roller 41a in FIG. 1 is heated, and the surface temperature of the roller is increased. On the other hand, when the voltage between the terminals p-q becomes 0, the halogen lamp 431 does not generate heat, and the surface temperature of the fixing roller 41a is lowered by natural cooling.
The thermostat 432 is a protection element that detects abnormal heating of the fixing roller 41a and cuts off the current.

(Heater switch circuit 76)
The heater switch circuit 76 (heating power supply unit 10) controls the phase of the AC voltage applied from the input terminals a and b of the power noise filter 73 when the switch is turned on (on state), so that the heater 43 Are output to the terminals p and q. The heater switch circuit 76 includes a phototriac 762, a main triac 763, and a transistor 764, and performs ON / OFF control and phase control.
The operation of the heater switch circuit 76 will be briefly described. First, when a current flows through the transistor 764, the phototriac 762 becomes conductive, and when a gate current flows through the gate terminal G of the main triac 763, the main triac 763 becomes conductive. As a result, the voltage applied from the input terminals a and b of the power noise filter 73 is applied to the main triac 763, and this voltage is applied to the heater 43 connected to the heater switch circuit 76.

  The transistor 764 turns on the heater switch circuit 76 when the heater control signal is received from the control unit 6 (heater control signal is ON), and does not receive the heater control signal (heater control signal is OFF). The heater switch circuit 76 is turned off. The transistor 764 has a base connected to the control unit 6 to receive a heater control signal, a cathode connected to a +5 [V] DC power supply, and an emitter grounded via a phototriac 762. Accordingly, when the transistor 764 receives the heater control signal (heater control signal is ON) and is in the on state, a current flows between the collector and the emitter of the transistor 764 and a current flows from the cathode of the light emitting diode 7621 to the emitter. As a result, current flows into the phototriac 762 (light emitting diode 7621 described later).

The phototriac 762 includes a light emitting diode 7621 (light emitting element) and a triac 7622 (light receiving element). The light-emitting diode 7621 has a cathode connected to the emitter of the transistor 764 and is connected to a +5 [V] DC power supply via the transistor 764. On the other hand, the anode is grounded. The triac 7622 has a terminal T3 connected to the gate terminal G of the main triac 763, and the terminal T4 is further connected to a terminal T1 of the main triac 763 and a terminal q (halogen lamp 431) of the heater 43 through resistors. The terminal T4 of the triac 7622 is connected to the input terminal a of the power noise filter 73 via a resistor.
As described above, in the phototriac 762, when the heater control signal is output from the control unit 6 (the heater control signal is ON), a current flows between the collector and the emitter of the transistor 764, so that the light emitting diode 7621 emits light. Then, the terminal T3 and the terminal T4 of the triac 7622 are connected, and an alternating current whose current is limited by the resistor flows. When the main triac 763 is turned on and the instantaneous value of the alternating current becomes equal to or lower than the holding current, the space between the terminal T3 and the terminal T4 of the triac 7622 is opened.

The main triac 763 has a gate terminal G connected to a terminal T3 of the phototriac 762, a terminal T1 connected to a terminal q of the heater 43, and one end of the phototriac 762 via a resistor. The terminal T2 of the main triac 763 is connected to the input terminal a of the power noise filter 73. The main triac 763 is opened at the zero cross point where the terminal pulse T1 and the terminal T2 are connected when the gate pulse current flows into the gate terminal G, and the instantaneous value of the alternating current becomes equal to or less than the holding current.
As described above, the main triac 763 also functions as a switch that connects / releases in response to the ON / OFF of the heater control signal from the control unit 6, similarly to the phototriac 762.

  When the control unit 6 outputs a pulse signal as a heater control signal, the heater switch circuit 76 connects the terminal T3 and the terminal T4 of the triac 7622 included in the phototriac 762 to thereby connect the gate pulse of the main triac 763. A current is passed to connect between the terminal T1 and the terminal T2. At this time, the triac 7622 is turned off because no current flows. As a result, in the heater switch circuit 76, only the main triac 763 is turned on, and an AC voltage is applied to the heater 43 (halogen lamp 431).

Then, the main triac 763 is turned off at the zero cross point where the instantaneous value of the alternating current is equal to or less than the holding current. That is, when the control unit 6 sets the generation timing of the pulse signal to the zero cross point of the AC voltage, the heater switch circuit 76 sets the energization time of the main triac 763 to the full cycle of the AC voltage, and the control unit 6 generates the pulse signal generation timing. Is shifted from the zero cross point by a predetermined phase angle, the heater switch circuit 76 can control the phase.
Therefore, when the control unit 6 outputs a repetitive pulse signal synchronized with the zero cross point as the heater control signal, the heater switch circuit 76 can phase control the heating power to the heater 43.

  On the other hand, when the controller 6 continues to output OFF as the heater control signal, the heater switch circuit 76 is turned off, the AC voltage applied to the heater 43 (halogen lamp 431) becomes 0, and the heating power to the heater 43 Is also 0.

  In the heating power supply unit 10 having the above configuration, when the power switch 71 is on, an AC voltage from the commercial power supply 8 is applied to the X capacitor 731 of the power noise filter 73 and the AC voltage is applied to the heater 43 (halogen). Applied to the lamp 431). On the other hand, at the moment when the power switch 71 is turned off, the application of the AC voltage to the X capacitor 731 is stopped, and the residual charge stored in the X capacitor 731 is discharged to the heater 43 (halogen lamp 431).

(Explanation of operation process after power switch OFF)
Processing performed by the control unit 6 after the user switches off the power switch 71 will be described with reference to FIGS. 5 and 6. The horizontal axis of FIG. 5 shows the passage of time. Time t1 is the time when the power switch 71 is switched from on to off. Time t2 is the time when the predetermined time TA has elapsed from time t1 and the control unit 6 determines that the power switch 71 is turned off based on the zero cross signal. Time t3 is the time when the discharge of the X capacitor 731 is completed (charging energy is 0). Time t4 is timing when the control unit 6 determines that the surface temperature of the fixing roller 41a has decreased.

<< t <t0 >>
First, the power switch 71 is on. At this time, the AC voltage of the commercial power supply 8 is applied to the input terminals a and b of the power noise filter 73 (FIG. 5A). Then, the AC zero-cross circuit 75 outputs a zero-cross signal to the control unit 6 at the timing when the instantaneous value of the AC voltage of the commercial power supply 8 becomes 0 (FIG. 5B). If the heater control signal is output from the control unit 6 (if a pulse signal synchronized with the zero cross signal continues to be output) (FIG. 5D), the commercial power source is supplied to the heater 43 via the heater switch circuit 76. 8 is applied, the halogen lamp 431 generates heat, and the fixing roller 41a in FIG. 2 is heated. As a result, the surface temperature of the fixing roller 41a increases, and the temperature data detected by the temperature detection sensor 42 also increases (FIG. 5C). Here, when the power switch 71 is in an ON state, an AC voltage is applied to the X capacitor 731 and energy of E is stored (FIG. 5E).

<< t = t0 >>
The control unit 6 acquires temperature data from the temperature detection sensor 42 and outputs a heater control signal (repetitive pulse train signal synchronized with the zero cross signal) so that the temperature data is within a predetermined range (from Hmax to Hmin). . For example, when the temperature data acquired from the temperature detection sensor 42 reaches Hmax at time t0 (FIG. 5C), the control unit 6 sets the heater at the timing of receiving the zero cross signal (FIG. 5B). No control signal is output (continuation of OFF) (FIG. 5 (d)). The heater switch circuit 76 that cannot receive the heater control signal switches from the on state to the off state, and continues to open the connection between the commercial power supply 8 and the heater 43. As a result, AC power from the commercial power supply 8 is not supplied to the heater 43 (halogen lamp 431).

<< t0 <t <t1 >>
After time t0, the halogen lamp 431 of the heater 43 does not generate heat, so the surface temperature of the fixing roller 41a gradually decreases. Therefore, the temperature data detected by the temperature detection sensor 42 is lowered (FIG. 5C).

<< t = t1 >>
When the user switches the power switch 71 from on to off at time t1, the commercial power supply 8 and the power supply unit 7 are not connected (FIG. 5A). As a result, no AC voltage is applied to the AC zero-cross circuit 75, so the AC zero-cross circuit 75 does not output a zero-cross signal (FIG. 5B).
The control unit 6 always acquires time data from the timer 94 when a zero cross signal is received from the AC zero cross circuit 75, and determines whether or not a predetermined time TA has elapsed until the next zero cross signal is received. (FIG. 6: Step S101). Here, the time TA is an arbitrary value.
If the next zero cross signal is received within the predetermined time TA (FIG. 6: step S101, No), the control unit 6 determines that the power switch 71 is on, performs the process of step S101 again, and performs the next zero cross. Wait for signal reception.
On the other hand, if the next zero cross signal has not been received within the predetermined time TA (the predetermined time TA has elapsed) (FIG. 6: Step S101, Yes), the control unit 6 determines that the power switch 71 is off. Determination is made (FIG. 6: Step S102).

<< Time t = t2 >>
Time t2 is the time at which a predetermined time TA has elapsed from time t1 (FIG. 5B).
The control unit 6 determines that the power switch 71 is OFF at time t2 (FIG. 6: Step S102), and acquires temperature data H1 from the temperature detection sensor 42 (main thermistor 421, side thermistor 422) (FIG. 6: Step S103). At this time, the control unit 6 also acquires time data from the timer 94. Then, the controller 6 outputs an ON heater control signal (repetitive pulse train signal synchronized with the zero cross signal) to the heater switch circuit 76 (step S104) (FIG. 5D).
If the control unit 6 outputs a heater control signal at the time t1, the control unit 6 outputs the heater control signal as it is at the time t2.

Since the main triac 763 (FIG. 4) is in an on state until the holding current becomes lower than the holding current, the X capacitor 731 and the heater 43 are connected via the heater switch circuit 76, and the residual charge stored in the X capacitor 731 is reduced. The heater 43 is discharged. The halogen lamp 431 of the heater 43 generates heat with the discharge power. Therefore, the temperature data detected by the temperature detection sensor 42 at this time is higher than the temperature data H1 in step S103.
Thereafter, the temperature data detected by the temperature detection sensor 42 when all the residual charges of the X capacitor 731 are discharged becomes the maximum temperature after the control unit 6 outputs the heater control signal to the heater switch circuit 76. Therefore, when the temperature data Hn acquired from the temperature detection sensor 42 is lower (temperature is low) than the temperature data Hn-1 acquired immediately before that, the control unit 6 determines that all the residual charges in the X capacitor 731 have been discharged. can do.

<< Time t2 <t <t3 >>
The controller 6 waits until a predetermined time TB elapses after acquiring the temperature data H1 from the temperature detection sensor 42 (main thermistor 421, side thermistor 422) (FIG. 6: step S105).
When a predetermined time TB has elapsed after acquiring the temperature data H1, the control unit 6 acquires the temperature data H2 from the temperature detection sensor 42 again (FIG. 6: Step S106). Then, the control unit 6 compares the temperature data H1 and the temperature data H2, and determines whether or not H1> H2 (FIG. 6: Step S107). Here, the control unit 6 acquires time data from the timer 94 when acquiring the temperature data H2.
If H1 ≦ H2 (FIG. 6: Step S107, No), all of the residual charges of the X capacitor 731 have not yet been discharged (the time t3 in FIG. 5 (d) has not been reached). S109 is executed.

<< Time t3 <t <t4 >>
If H1> H2 (FIG. 6: Step S107, Yes), the control unit 6 has acquired temperature data H2 having a temperature lower than the temperature data H1 acquired immediately before. As a result, it is determined that all the residual charges of the X capacitor 731 have been discharged (time t3 in FIG. 5E has elapsed), and the control unit 6 stops outputting the heater control signal (continuation of OFF). State) (FIG. 6: Step S108) (time t4 in FIG. 5D). Then, the process ends.
Time t4 is the time when the control unit 6 acquires temperature data Hn having a temperature lower than the temperature data Hn-1 acquired immediately before.

(Step S109)
On the other hand, if H1 ≦ H2 in step S107 (FIG. 6: step S107, No), then the control unit 6 compares the threshold value Hd stored in advance in the storage unit 93 with the temperature data H2. , H2> Hd is determined (FIG. 6: step S109).
This threshold value Hd is a value obtained when the temperature data detected by the temperature detection sensor 42 at time t1 is Hmax and the charge is accumulated in the X capacitor 731 up to the maximum voltage. The temperature is higher than the maximum value (Hz) of the temperature data detected by the temperature detection sensor 42. That is, when H2> Hd, the control unit 6 can determine that a voltage from other than the X capacitor 731 is applied to the heater 43.

  In step S109, if H2 ≦ Hd (FIG. 6: step S109, No), it is determined that electric charge still remains in the X capacitor 731 (residual electric charge is being discharged), and the control unit 6 determines that the heater switch The heater control signal remains output to the circuit 76 (continuation state of heater control signal ON). And the control part 6 hold | maintains the temperature data H2 acquired by step S106 as temperature data H1 (step S110), returns to step S105, and acquires the temperature data H1 (that is, temperature data H2 by step S106). Wait until a predetermined time TB elapses.

  On the other hand, if H2> Hd in step S109 (FIG. 6: Yes in step S109), the control unit 6 determines that a voltage from other than the X capacitor 731 is applied to the heater 43, and first, the heater Output of the control signal is stopped (continuation state of heater control signal OFF) (FIG. 6: Step S111). Furthermore, the control unit 6 notifies the user that an abnormality has occurred (FIG. 6: step S112). At this time, the control unit 6 outputs a warning display or a warning sound to a display unit or a speaker (not shown) included in the image forming apparatus 1 to notify the user that an abnormality has occurred. Then, the control unit 6 ends the operation process after the power switch is turned off.

  Here, as a case where H2> Hd is satisfied in step S109, it is conceivable that the AC zero cross circuit 75 fails and the zero cross signal is not output even though the power switch 71 is ON. In this case, since the voltage of the commercial power source 8 is continuously applied to the heater 43 via the heater switch circuit 76, the temperature detection sensor 42 can detect temperature data exceeding Hd.

  In the present embodiment, the AC-DC converter 74 has a time t4 after the user turns off the power switch 71 at time t1 because the output voltage holding time exists or the controller 6 is backed up by the battery. Thus, a sufficient voltage for processing is applied to the control unit 6 for a time until the control unit 6 stops outputting the heater control signal (continuation state of OFF).

As described above, according to this embodiment, even after the power switch 71 is turned off by the user, the residual charge accumulated in the X capacitor 731 is discharged to the halogen lamp 431 of the heater 43 via the main triac 763. . Further, the power switch 71 may be turned off when the phase of the main triac 763 is controlled for temperature control and the main triac 763 is in the OFF state. Even at this time, the control unit 6 detects that the reception of the zero-cross signal is interrupted, and sends a heater control signal (pulse signal) to the heater switch circuit 76. As a result, the main triac 763 is forcibly turned on, and the residual charge accumulated in the X capacitor 731 is discharged via the main triac 763.
Therefore, even if a discharge resistor is not connected in parallel with the X capacitor 731, the residual charge accumulated in the X capacitor 731 can be consumed when the power switch 71 is turned off by the user.
Moreover, according to this embodiment, since it is a circuit structure which does not connect a discharge resistor in parallel with X capacitor | condenser 731, when the power switch 71 is ON, the power consumed by a discharge resistor can be reduced.

<< Second Embodiment >>
The image forming apparatus of the present invention will be described with reference to FIG.
(Heater switch circuit 76A)
A heater switch circuit 76A (heating power supply unit 10) of the second embodiment shown in FIG. 7 is a modification of the heater switch circuit 76 of the first embodiment.

  One end of the coil 761 is connected to the input terminal a of the power noise filter 73 and the other end is connected to a terminal T4 of the triac 7622 of the phototriac 762 via a resistor.

  The phototriac 762 includes a light emitting diode 7621 (light emitting element) and a triac 7622 (light receiving element). The light-emitting diode 7621 has a cathode connected to the emitter of the transistor 764 and is connected to a +5 [V] DC power supply via the transistor 764. On the other hand, the anode is grounded. The triac 7622 has a terminal T3 connected to the gate terminal G of the main triac 763 and the terminal q (halogen lamp 431) of the heater 43 via a resistor. The terminal T4 of the triac 7622 is connected to the input terminal a of the power noise filter 73 through a resistor and a coil 761.

  In the main triac 763, the gate terminal G is connected to the terminal T3 of the phototriac 762 via a resistor, and the terminal T1 is connected to the terminal p of the heater 43. The terminal T2 of the main triac 763 is connected to the input terminal a of the power noise filter 73 via a resistor.

  The present invention is not limited to the above-described embodiment, and various changes and modifications can be made without departing from the gist of the present invention.

For example, in the first or second embodiment, when the control unit 6 determines that the power switch 71 is turned off (step S102 in FIG. 6), the control unit 6 acquires time data from the timer 94 and starts from that time. The heater control signal may be turned OFF when the elapsed time has passed a predetermined time tz.
This time tz is a sufficient time from when the power switch 71 is turned off by the user until all the residual charges stored in the X capacitor 731 are discharged to the heater 43. The internal resistance of the heater and the X capacitor It is a value determined on the basis of the capacity. The time tz is data stored in advance in the storage unit 93.
This is an effective means when the temperature data detected by the temperature detection sensor 42 does not exceed the threshold value Hd even though the AC zero cross circuit 75 has failed, and an abnormality occurs at the timing when the time tz has elapsed. Can be notified to the user.

In each of the above-described embodiments, a triac that is turned off below the holding current is used for the heater switch circuit 76. However, a switching element such as an FET (Field Effect Transistor) can also be used. In this case, although there are restrictions such as power saving, the ON / OFF state can be controlled only by the gate voltage, and in step S109 in FIG. The controller 6 can continue the residual discharge by keeping the heater control signal output to the heater switch circuit 76.
That is, the control unit 6 controls the heater switch circuit to electrically connect the X capacitor 731 and the heater 43 when the next zero cross signal cannot be received within a predetermined time after receiving the zero cross signal. Can be connected.

DESCRIPTION OF SYMBOLS 1 Image forming apparatus 2 Paper feeding part 3 Image forming part 4 Fixing part 5 Paper conveyance part 6 Control part 7 Power supply part 8 Commercial power supply 10 Heating power supply part 20 Paper 21 Paper cassette 22 Pickup roller 31 Developing apparatus 32 LED head 33 Transfer roller 41a, 41b Fixing roller 42 Temperature detection sensor 43 Heater 50 Transport path 51 (51a, 51b) Registration roller 52 Transfer belt 52a, 52b Drive roller 53 Discharge roller 71 Power switch 72 Protection element 73 Power noise filter 74 AC-DC converter 75 AC Zero Cross Circuit 76 Heater Switch Circuit 91 Communication Unit 92 Actuator Control Unit 93 Storage Unit 94 Timer 311 Toner Cartridge 312 Toner Supply Roller 313 Development Roller 314 Charging Roller 315 Photosensitive Drum 431 Halogen Lamp 432 Thermostat 731 X capacitor 732 common mode choke coil 733 and 734 Y capacitor 751 trans 752 rectifier circuit 753 photocoupler 754 Schmitt trigger 761 coil 762 phototriac 763 main Triac 764 transistor 931 ROM
932 RAM
7531 Light Emitting Diode 7532 Phototransistor 7621 Light Emitting Diode 7622 Triac

Claims (5)

An image forming apparatus comprising a capacitor connected in parallel with both ends of a commercial power supply and a heater that heats AC power supplied from the commercial power supply and the capacitor,
An image forming apparatus according to claim 1, wherein when the AC power supplied from the commercial power source is cut off, residual charges remaining in the capacitor are discharged to the heater. A zero-cross detection circuit for detecting a zero-cross point of the voltage across the capacitor;
A heater switch circuit inserted between the commercial power source and the capacitor and the heater;
And a controller that electrically connects the heater switch circuit when the next zero-cross point cannot be detected within a predetermined time after the zero-cross detection circuit detects the zero-cross point. The image forming apparatus according to claim 1. The capacitor is a normal mode noise removing capacitor of 0.1 μF or more,
The image forming apparatus according to claim 1, wherein a discharge resistor is not connected to both ends of the capacitor.   The image forming apparatus according to claim 2, wherein the heater switch circuit performs energization control using a triac. An image forming apparatus comprising: a capacitor that is detachably connected in parallel to both ends of a commercial power supply, and a discharge resistor is not connected to both ends; and a heater that heats AC power supplied from the commercial power supply and the capacitor. And
An image forming apparatus according to claim 1, wherein when the AC power supplied from the commercial power source is cut off, residual charges remaining in the capacitor are discharged to the heater.

Images