JP6351345B2 - Image forming apparatus - Google Patents

Description

  The present invention relates to an image forming apparatus including a fixing device (heating device) that fixes a toner image on a recording material, and more particularly to an image forming device having a universal power source.

  In an image forming apparatus such as a copying machine or a printer using an electrophotographic system, there is a heating type fixing device that fixes an unfixed image on a recording material by heating the recording material having a toner image formed on the surface thereof. Widely used. In a heating-type fixing device, a configuration in which an AC voltage of a commercial AC power source is supplied to a heating element in the fixing device is often used. Further, the power supply circuit unit of the image forming apparatus is provided with an AC / DC converter, and the AC / DC converter converts an input AC voltage into a desired DC voltage, and a control unit, a drive unit, and the like in the image forming apparatus. The image forming operation is performed by supplying to

  In the power supply circuit section, the AC / DC converter provided in the power supply circuit section is doubled as one of means for designing a power supply (hereinafter also referred to as a universal power supply) that can handle either a commercial AC power supply voltage of 100V or 200V. A configuration using a voltage circuit is known. For example, Patent Document 1 discloses a configuration that includes a voltage doubler circuit and switches the voltage doubler circuit and the control method of the fixing device based on the detection result of the input voltage.

Japanese Patent Laid-Open No. 04-226480

  However, the universal power source using the voltage doubler circuit as in the conventional example has the following problems. The voltage doubler circuit uses an AC voltage input voltage detection circuit provided separately from the voltage doubler circuit, and the operation is switched according to the voltage value of the input AC power supply. For this reason, when the input voltage detection circuit erroneously detects the input voltage (100 V system / 200 V system) for some reason, the voltage doubler circuit cannot be appropriately switched with respect to the input voltage. In particular, when the AC power supply voltage is erroneously detected as being 100V despite being 200V, the voltage applied to the smoothing capacitor provided downstream of the voltage doubler rectifier circuit is doubled by 200V. The voltage will be. In the conventional example, the following measures are taken in order to prevent such a situation from occurring and to prevent the above-described problem from occurring even if such a situation occurs. That is, measures are taken to increase the robustness or to increase the rated voltage of the smoothing capacitor so that a large voltage may be input to the input voltage detection circuit. For this reason, in any case, there is a problem of circuit complexity and circuit cost increase.

  The present invention has been made under such circumstances, and an object thereof is to simply configure a universal power source and to improve robustness while reducing costs.

  In order to solve the above-described problems, the present invention has the following configuration.

(1) A power supply circuit having a rectifying means for double voltage rectification or full-wave rectification of an input AC voltage and an unfixed toner image formed on the recording material by the image forming means are fixed on the recording material, and the first whether it is compatible with the fixing means into an AC voltage of, or to have a first storage means for storing the information indicating which conforms fixing means to the first AC voltage the second AC voltage is greater than An image forming apparatus comprising: a fixing unit; a voltage detecting unit configured to detect the AC voltage; a type detecting unit configured to detect a type of the fixing unit based on the information stored in the first storage unit ; in a case where the type types are compatible AC voltage and the AC voltage detected Ri by said voltage detecting means of the fixing means Ri has been detected by the detection means coincide, the matching AC voltage first alternating voltage If it is, the rectifying means Switch to the voltage doubler rectification, the kind if a matching AC voltage on the type of the fixing means detected by the detecting means and said voltage AC voltage detected by the detection means do not match, and the matching AC voltage the second An image forming apparatus comprising: switching means for switching to full-wave rectification when the AC voltage is 2 .

  According to the present invention, the universal power source can be simply configured, and the robustness can be enhanced while reducing the cost.

Schematic diagram of image forming apparatus of Examples 1 to 4, schematic diagram of fixing device and ceramic heater Circuit block diagram of driving circuit of ceramic heater and switching power source of Examples 1 to 4 The circuit block diagram of the AC / DC converter 60 of Examples 1-3, the waveform figure of each part, the relationship diagram of an effective voltage and AD conversion value Circuit diagram of AC / DC converter 61 of Examples 1 to 3, waveform diagram when voltage doubler control is not performed Circuit configuration diagram of AC / DC converter 61 of Embodiments 1 to 3, waveform diagram when voltage doubler control is performed Flowchart showing type discrimination processing and voltage detection processing according to the first embodiment. The flowchart which shows the double voltage switching process of Example 1. Flowchart showing type discrimination processing and voltage doubler switching processing of the second embodiment. Flowchart showing type discrimination processing of embodiment 3 FIG. 7 is a circuit block diagram of a switching power supply according to a fourth embodiment, and a flowchart illustrating voltage doubler switching processing.

  DESCRIPTION OF EMBODIMENTS Hereinafter, embodiments for carrying out the present invention will be described in detail by way of examples with reference to the drawings.

[Image forming apparatus]
A color image forming apparatus (hereinafter referred to as a main body) shown in FIG. 1A includes process cartridges 5Y, 5M, 5C, and 5K that are detachable from the main body. These four process cartridges 5Y, 5M, 5C, and 5K have the same structure, but images of toners of different colors, that is, yellow (Y), magenta (M), cyan (C), and black (K) are displayed. It differs in the point to form. Hereinafter, the Y, M, C, and K subscripts are omitted unless necessary. The process cartridge 5 includes a toner container 23, a photosensitive drum 1 as an image carrier, a charging roller 2, a developing roller 3, a drum cleaning blade 4, and a waste toner container 24. A laser unit 7 is disposed below the process cartridge 5 and performs exposure based on an image signal to the photosensitive drum 1. The photosensitive drum 1 is charged to a predetermined negative potential by the charging roller 2, and then an electrostatic latent image is formed by the laser unit 7. The electrostatic latent image is reversely developed by the developing roller 3 and negative toner is attached to form Y, M, C, and K toner images, respectively.

  The intermediate transfer belt unit includes an intermediate transfer belt 8, a driving roller 9, and a secondary transfer counter roller 10. Further, a primary transfer roller 6 is disposed inside the intermediate transfer belt 8 so as to face each photosensitive drum 1, and a transfer voltage is applied by a power source which is an application unit (not shown). When an image forming operation is being performed, each photosensitive drum 1 is rotated in the clockwise direction (the arrow direction in the figure), and the intermediate transfer belt 8 is moving in the arrow A direction. The toner images are sequentially transferred onto the intermediate transfer belt 8 from the toner image on the photosensitive drum 1Y by the primary transfer roller 6 to which a positive voltage is applied. As a result, when the toner image on the photosensitive drum 1K is transferred onto the intermediate transfer belt 8, a full-color toner image in which the four color toner images overlap is formed. The full-color toner image on the intermediate transfer belt 8 is conveyed to the secondary transfer roller 11 as the intermediate transfer belt 8 moves.

  The paper feeding / conveying device 12 includes a paper feeding roller 14 that feeds the recording paper P from a paper feeding cassette 13 that stores the recording paper P that is a recording material, and a transport roller pair 15 that transports the fed recording paper P. have. The recording paper P conveyed from the paper feeding / conveying device 12 is conveyed to the secondary transfer roller 11 by the registration roller pair 16. In the transfer from the intermediate transfer belt 8 to the recording paper P, by applying a positive voltage to the secondary transfer roller 11, four color toner images on the intermediate transfer belt 8 are transferred to the conveyed recording paper P. Transcribed. The recording paper P onto which the unfixed toner image has been transferred is conveyed to a fixing device 17 that is a fixing means, heated and pressed by a fixing film 18 in which a ceramic heater 30 is inscribed, and a pressure roller 19, and the surface The toner image is fixed to the toner image. The fixed recording paper P is discharged by the paper discharge roller pair 20. On the other hand, the toner remaining on the surface of the photosensitive drum 1 after the toner image is transferred is removed by the drum cleaning blade 4. Further, the toner remaining on the intermediate transfer belt 8 after the toner image is transferred to the recording paper P is removed by the transfer belt cleaning blade 21, and the removed toner is collected in the waste toner collecting container 22.

  The control board 25 is a board on which an electric circuit for controlling the main body is mounted, and the CPU 26, ROM 26a, RAM 26b, and nonvolatile memory 26c are mounted on the control board 25. The CPU 26 collectively performs operations of the main body such as control of a drive source (not shown) related to conveyance of the recording paper P and a drive source (not shown) of the process cartridge 5, control related to an image forming operation, and control related to failure detection. I have control. Further, the switching power supply 27 converts the AC voltage of the AC power input from the power cable 28 into a DC voltage used in the main body and supplies it to the main body such as the control board 25.

[Fixing device]
FIG. 1B is a side view of the fixing device 17. The fixing device 17 is a general film heating type fixing device. A ceramic heater 30 and a holding member (not shown) are provided inside the fixing film 18. The ceramic heater 30 faces the pressure roller 19. Are arranged. As the fixing film 18, for example, a cylindrical film such as PTFE or PFA having heat resistance, strength, durability, or the like is used. The pressure roller 19 is an elastic roller configured by concentrically and integrally providing a heat-resistant elastic layer 32 such as silicone rubber on the outer periphery of the cored bar 31 on the roller.

  As shown in FIG. 1C, the ceramic heater 30 of the present embodiment is a member that is elongated in a direction (hereinafter also referred to as a longitudinal direction) orthogonal to the conveyance direction of the recording paper P (black arrow in the figure). In the ceramic heater 30, for example, a heating element 35, conductive portions 36 a and 36 b, and electrode portions 37 a and 37 b are respectively formed on an aluminum nitride (AlN) base material 34. The heating element 35 is covered with a glass protective film 38 as an electrical insulating layer.

  The image forming apparatus according to the present exemplary embodiment can be equipped with at least two or more types of fixing devices corresponding to an input AC voltage. In this embodiment, the fixing device 17 to be mounted on the main body is prepared in two types of 100V system and 200V system corresponding to the AC voltage of the commercial power source in the area where the image forming apparatus is installed. For example, when the AC voltage of the commercial power source is a 100V system, the resistance value of the heating element 35 is 10Ω. On the other hand, when the AC voltage of the commercial power supply is 200V, the resistance value of the heating element 35 is 40Ω. Further, a thermistor 33 that is a temperature detecting means used for temperature control of the ceramic heater 30 is provided near the center of the ceramic heater 30 in the longitudinal direction.

[Circuit configuration of fixing device]
FIG. 2A is a diagram illustrating a drive circuit of the ceramic heater 30 and a circuit configuration of the fixing device 17. 2A, a relay 42 is connected to the neutral side of the AC power supply 41, and a relay 43 is connected to the live side. The relay 43 is connected to a thermo switch 40, a ceramic heater 30, and a bidirectional thyristor (hereinafter referred to as triac) 44. The relays 42 and 43 cut off the power supply line to the ceramic heater 30 when necessary. The relays 42 and 43 are driven by a relay drive circuit based on drive signals output from the P1 terminal and the P2 terminal of the CPU 26, respectively. Here, the drive circuit of the relay 42 includes a resistor 45 and a transistor 46. The CPU 26 outputs, for example, a high level drive signal from the P1 terminal to turn on the transistor 46, connects the relay 42, outputs a low level drive signal, turns off the transistor 46, and disconnects the relay 42. The drive circuit for the relay 43 includes a resistor 55 and a transistor 56. The CPU 26 outputs, for example, a high level drive signal from the P2 terminal to turn on the transistor 56, connects the relay 43, outputs a low level drive signal, turns off the transistor 56, and disconnects the relay 43.

  The power supply to the ceramic heater 30 is turned on or off by the triac 44. The CPU 26 outputs, for example, a high-level heater drive signal from the P3 terminal to the transistor 49 of the triac drive circuit, thereby turning on the transistor 49 and lighting the LED of the phototriac coupler 50. Here, the triac drive circuit includes resistors 47 and 48 and a transistor 49. When the LED of the phototriac coupler 50 is lit, the phototriac coupler 50 is turned on, and the triac 44 is turned on by the bias resistors 51 and 52 of the triac 44. Here, reference numeral 53 denotes a triac surge protection component.

  The thermistor 33 detects the temperature of the ceramic heater 30. The analog voltage value divided by the thermistor 33 and the resistor 54 is input to the P4 terminal of the CPU 26 as temperature information. The CPU 26 controls the driving of the triac 44 based on the temperature information input to the P4 terminal. As a result, the CPU 26 controls the temperature of the ceramic heater 30 to be constant. The zero cross detector 57 detects the zero cross point of the AC voltage waveform of the AC power supply 41 and outputs it as a zero cross signal to the P5 terminal of the CPU 26. The CPU 26 performs drive control of the triac 44 by determining the timing for turning on the triac 44 in synchronization with the zero cross signal input to the P5 terminal from the zero cross detector 57.

  The thermo switch 40 is a safety protection element connected between the AC power supply 41 and the heating element 35, and shuts off the power supply path when the temperature of the ceramic heater 30 reaches the operating temperature of the thermo switch 40. The pull-up resistor 39 is a resistor for detecting the connection of the fixing device 17, and the resistor 39 is connected to the P6 terminal of the CPU 26 and the ground (GND) in the fixing device 17. The CPU 26 can determine whether or not the fixing device 17 is mounted on the main body by checking the level of the signal input to the P6 terminal. Specifically, the CPU 26 determines that the fixing device 17 is attached if the signal input to the P6 terminal is at a low level, and determines that the fixing device 17 is not attached if the signal is at a high level. Thus, the CPU 26 functions as a mounting detection unit that detects whether or not the fixing device 17 is mounted.

  As described above, the fixing device 17 of the present embodiment has a resistance value of the heating element 35 of 100V / 200V. For this reason, it is configured to determine whether the fixing device 17 is compatible with the 100V system or the 200V system depending on whether the resistor 58 in the fixing device 17 is mounted or not. The determination of whether the fixing device 17 is compatible with the 100V system or the 200V system is hereinafter referred to as type determination. The resistor 58 in the fixing device 17 is connected to a pull-down resistor 59 provided on the main body side, and the voltage divided by the resistors 58 and 59 is input to the P7 terminal of the CPU 26. In this embodiment, the resistance value of the resistor 58 is 10 kΩ, and the resistance value of the resistor 59 is 100 kΩ. By mounting the resistor 58 on the fixing device 17 suitable for the 100V system, the level of the voltage input to the P7 terminal of the CPU 26 becomes a high level of Vcc × 0.91 [V]. On the other hand, in the fixing device 17 suitable for the 200V system, the resistor 58 is not mounted (not mounted), so that the voltage level input to the P7 terminal of the CPU 26 becomes a low level pulled down by the resistor 59. As described above, the CPU 26 determines whether the fixing device 17 mounted on the main body is a model compatible with the 100V system or a model compatible with the 200V system (fixing device type) based on the level of the voltage input to the P7 terminal. Can be determined. That is, the CPU 26 functions as a type detection unit that detects the type of the fixing device 17. Note that the fixing device 17 shown in FIG. 2A is equipped with a resistor 58, and a high-level voltage is input to the P7 terminal of the CPU 26, so that the model is compatible with the 100V system. The voltage Vcc and voltage Vm in FIG. 2A will be described later.

[Switching power supply]
Next, the switching power supply 27 of the present embodiment will be described with reference to FIGS. FIG. 2B is a block diagram of the switching power supply 27 according to the present embodiment. The AC power supply 41 includes two AC / DC converters 60 and 61. The AC / DC converter 60 serving as the power supply circuit and the first conversion means generates a DC voltage having a voltage value Vcc [V] that is the first DC voltage while the AC voltage is supplied from the AC power supply 41. ing. The AC / DC converter 60 is a universal power supply circuit in which the voltage of the AC power supply 41 is compatible with both 100V / 200V systems. In this embodiment, the voltage Vcc generated by the AC / DC converter 60 is used for the operation of the main body control system such as the CPU 26.

  On the other hand, the AC / DC converter 61 which is the second conversion means is a power supply including a voltage doubler circuit, and generates a DC voltage having a voltage value Vm [V] which is a second DC voltage. The AC / DC converter 61 can be switched between voltage doubler rectification or full wave rectification by the CPU 26. That is, the CPU 26 functions as a switching unit. The AC / DC converter 61 is a power supply circuit that can turn on or off the output of the AC / DC converter 61 by the CPU 26. In this embodiment, the voltage Vm generated by the AC / DC converter 61 is used for an actuator operation such as a motor related to an image forming operation.

(AC / DC converter 60)
FIG. 3A shows a specific circuit configuration of the AC / DC converter 60. FIG. 3A is a circuit diagram of the AC / DC converter 60 of the present embodiment. The AC / DC converter 60 is a flyback power source having a fixed oscillation frequency as an example. The AC voltage supplied from the AC power supply 41 is rectified and smoothed by the diode bridge 62 and the primary smoothing capacitor 63 to become a substantially constant voltage Vp. This voltage Vp is supplied to a field effect transistor (hereinafter referred to as FET) 66 through a transformer 65. The driving circuit 64 turns on or off the FET 66 to control an operation for supplying and interrupting a current flowing through the primary winding 65a of the transformer 65 (hereinafter referred to as a switching operation), whereby a pulse is applied to the secondary winding 65b of the transformer 65. A voltage is induced. The pulse voltage induced in the secondary winding 65b of the transformer 65 is rectified and smoothed by the secondary side rectifier diode 67 and the secondary side smoothing capacitor 68 to become a predetermined voltage Vcc, and is supplied to the load 69. Here, as described above, the load 69 connected to the secondary side of the AD / DC converter 60 is a load of the main body control system including the CPU 26.

  An input voltage detection circuit 77 as voltage detection means is connected to the anode terminal of the secondary side rectifier diode 67. Hereinafter, the operation of the input voltage detection circuit 77 will be described with reference to FIG. The input voltage detection circuit 77 includes a diode 70, an inverting amplifier circuit, and a peak hold circuit. Here, the inverting amplifier circuit includes resistors 71 and 72 and an operational amplifier 73, and the peak hold circuit includes a diode 74, a capacitor 75, and a resistor 76.

  3B is a voltage waveform (gate waveform) of the gate terminal of the FET 66, and FIG. 3C is a voltage waveform (anode waveform) of the anode terminal of the secondary side rectifier diode 67 according to the on / off of the FET 66. Is shown. FIG. 3D shows the waveform of the voltage Vvp output from the input voltage detection circuit 77. When the gate voltage of the FET 66 shown in FIG. 3B is at a high level, the FET is turned on. As shown in FIG. 3C, the voltage at the anode terminal of the secondary side rectifier diode 67 has an amplitude of −Vlow [V] when the FET 66 is on, and an amplitude of (Vcc + Vf) [V when the FET 66 is off. ]. Here, Vf is a forward voltage of the secondary side rectifier diode 67. The negative voltage portion of the waveform of the voltage at the anode terminal of the secondary side rectifier diode 67 is shaped by the diode 70 and is input to the inverting amplifier circuit composed of the operational amplifier 73.

In FIG. 3D, the output of the inverting amplifier circuit is indicated by a broken line, and the output of the inverting amplifier circuit has a pulse waveform. At this time, the broken line high-level voltage Vvp can be expressed by the following equation (1), where α is the gain of the inverting amplifier circuit.
Vvp = α × Vlow (1)
Further, the voltage Vlow can be expressed by the following equation (2) using the terminal voltage Vp of the primary smoothing capacitor 63, the number of turns N1 of the primary winding 65a of the transformer 65, and the number of turns N2 of the secondary winding 65b.
Vlow = Vp × N2 / N1 (2)
Further, the following approximate expression (3) is established between the effective value Vin of the voltage (sine wave voltage) of the AC power supply 41 and the terminal voltage Vp of the primary smoothing capacitor 63.
Vp = √2 × Vin (3)
Therefore, the following expressions (4) and (5) are established.
Vvp = √2 × α × Vin × N2 / N1 (4)
Vin = N1 × Vvp / (√2 × α × N2) (5)

That is, the effective value Vin of the voltage (sine wave voltage) of the AC power supply 41 is proportional to the high-level voltage Vvp of the inverting amplifier circuit. The output pulse of the inverting amplifier circuit indicated by the broken line in FIG. 3D is converted into a DC voltage of approximately Vvp by the subsequent peak hold circuit and input to the A / D port of the CPU 26. That is, the input voltage detection circuit 77 outputs the voltage Vvp to the CPU 26. The CPU 26 converts the input voltage Vvp from an analog value to a digital value with a resolution of, for example, 8 bits based on the following equation (6) (the converted value is referred to as an AD conversion value).
AD conversion value = Vvp / Vcc × 255 (6)
That is, from the AD conversion value of the voltage Vvp, the voltage Vvp output from the input voltage detection circuit 77, the gain α of the inverting amplifier circuit, the number of turns N1 of the primary winding 65a of the transformer 65, and the number of turns N2 of the secondary winding 65b, Based on (5), the effective value voltage Vin of the AC power supply 41 can be obtained.

  In this embodiment, in order to obtain the effective value Vin of the voltage of the 100V / 200V AC power supply 41, the maximum voltage generated in the voltage Vvp output from the input voltage detection circuit 77 is higher than the power supply voltage Vcc of the CPU 26. Must be set to a low value. In this embodiment, Vcc = 3.3 [V], the maximum value of Vin is 264 [V] (240 [V] + 10%), and the value of α × N2 / N1 is 0.0088. Then, the relationship between the effective value Vin [V] of the voltage of the AC power supply 41 and the AD conversion value [dec] that is a result after AD conversion of the CPU 26 is as shown in FIG.

  Here, in FIG. 3E, the horizontal axis represents the effective value Vin [V] of the voltage of the AC power supply 41, and the vertical axis represents the AD conversion value [dec] after conversion of the voltage Vvp input to the A / D port of the CPU 26. ]. From FIG. 3E, when determining whether the AC power supply 41 is 100V system / 200V system, it is possible to determine 150 [dec] as a threshold value in the AD conversion value of the CPU 26. That is, the CPU 26 determines that the AC power supply 41 is 100V system if the AD conversion value is 150 [dec] or less, and determines that the AC power supply 41 is 200V system if the AD conversion value is greater than 150 [dec]. To do. Note that the configurations of the switching power supply 27 and the input voltage detection circuit 77 of this embodiment can be changed as appropriate, and are not limited to the contents described in this embodiment.

(AC / DC converter 61)
FIG. 4A shows a specific circuit configuration of the AC / DC converter 61. FIG. 4A is a circuit diagram of the AC / DC converter 61 of the present embodiment, which is the same flyback power supply as the AC / DC converter 60. The difference from the AC / DC converter 60 is that the AC / DC converter 61 has a voltage doubler circuit. Here, only the operation of the voltage doubler circuit of the AC / DC converter 61 will be described, and description of other circuit operations will be omitted.

  The AC voltage supplied from the AC power supply 41 is rectified and smoothed by the diode bridge 80 and the primary smoothing capacitors 81 and 82 to become a substantially constant voltage Vp. This voltage Vp is supplied to the FET 85 via the primary winding 84a of the transformer 84. When the FET 85 is switched by the drive circuit 83, a pulse voltage is induced in the secondary winding 84b of the transformer 84. The pulse voltage induced in the secondary winding 84b of the transformer 84 is rectified and smoothed by the secondary side rectifier diode 86 and the secondary side smoothing capacitor 87 to become a predetermined voltage Vm, and a load 88 (for example, a motor or the like) Actuator load).

  The connection point between the primary smoothing capacitors 81 and 82 is connected between the diode bridge 80 and the AC power supply 41 via a relay 89. The relay 89 is driven by the CPU 26. The CPU 26 outputs a high level signal to the base terminal of the transistor 92 to drive the transistor 92, thereby causing the LED in the photocoupler 95 to emit light. The resistor 96 is a resistor for limiting the current flowing through the LED in the photocoupler 95. When the LED in the photocoupler 95 emits light, the phototransistor in the photocoupler 95 is turned on, a current flows through the coil of the relay 89, and the contact of the relay 89 becomes conductive. For the power supply voltage Vd on the coil side of the relay 89, for example, an auxiliary winding (not shown) is provided in the transformer 65 of the AC / DC converter 60, and the voltage obtained from the auxiliary winding can be used as the power supply voltage Vd.

  A triac 78 as a switch means is a switch for turning on or off the AC / DC converter 61, and a triac is used in this embodiment. The CPU 26 turns on or off the triac 78 via the drive circuit 79. The circuit configuration of the drive circuit 79 of the triac 78 is the same as that of the triac 44 shown in FIG. Here, in FIG. 4A, the current path when the relay 89 is not conducted, that is, when the voltage doubler control is not performed is indicated by a thick solid line and a broken line. 4B shows the waveform of the AC voltage of the AC power supply 41, and FIG. 4C shows the waveform of the voltage Vp applied to both ends of the primary smoothing capacitors 81 and 82 when the voltage doubler control is not performed. The horizontal axis is time. In addition, the waveform shown with the dotted line of FIG.4 (c) shows the waveform after rectifying the alternating voltage of the alternating current power supply 41. FIG. In FIG. 4C, the waveform of the AC power supply 41 is full-wave rectified by the diode bridge 80, and the DC voltage Vp smoothed by the primary smoothing capacitors 81 and 82 is generated. Here, the relationship between the effective value Vin of the voltage of the AC power supply 41 and the generated DC voltage Vp is the relationship of the above-described equation (3).

FIG. 5A shows the current path when the relay 89 is turned on, that is, when voltage doubler control is performed, by a thick solid line and a broken line. 5B shows the waveform of the AC voltage of the AC power supply 41, FIG. 5C shows the waveform of the voltage Vc1 applied to both ends of the primary smoothing capacitor 81, and FIG. 5D shows the both ends of the primary smoothing capacitor 82. The waveform of the voltage Vc2 applied to each is shown. Further, FIG. 5E shows a waveform of the voltage Vp applied to both ends of the primary smoothing capacitors 81 and 82. The horizontal axis in FIGS. 5B to 5E is time. The waveforms shown by the dotted lines in FIG. 5C and FIG. 5D show the waveforms after the AC voltage of the AC power supply 41 is rectified. The waveform indicated by the dotted line in FIG. 5 (e) is a combination of the waveforms indicated by the dotted lines in FIG. 5 (c) and FIG. 5 (d). As shown by the current path in FIG. 5 (a), the AC voltage waveform of the AC power supply 41 is half-wave rectified by the diode bridge 80, and the DC voltage smoothed by the primary smoothing capacitors 81 and 82 is converted into the primary smoothing capacitor 81, The voltages Vc1 and Vc2 at both ends of 82 are obtained. That is, as a result of performing voltage doubler control on the AC voltage of the AC power supply 41, the DC voltage Vp generated at both ends of the primary smoothing capacitors 81 and 82 has the relationship of the following equation (7).
Vp = Vc1 + Vc2 (7)
Here, for the voltage Vc1 and the voltage Vc2, the following approximate expressions (8) and (9) are established using the voltage effective value Vin of the AC power supply 41.
Vc1 = √2 × Vin (8)
Vc2 = √2 × Vin (9)
Therefore, the following expression (10) is established by performing the voltage doubler control.
Vp = Vc1 + Vc2 = 2 × √2 × Vin (10)

[Fixing device type identification, voltage detection, voltage doubler switching processing]
(Fixing device type discrimination processing)
Next, the flow of type determination of the fixing device 17, detection of the voltage of the AC power supply 41, and switching of the double voltage will be described with reference to the flowchart of FIG. FIG. 6A is a flowchart showing a flow of type determination of the fixing device 17 by the CPU 26 of this embodiment. It is assumed that information regarding the type determination of the fixing device 17 in the RAM 26b stores information of “no fixing device type information” as an initial value. In step (hereinafter referred to as S) 801, the CPU 26 determines whether or not the main body is turned on (ON). If it is determined that the main body is not turned on, the processing of S 801 is repeated, and the main body is turned on. If it is determined to be on, the process proceeds to S802. In S <b> 802, the CPU 26 determines whether or not the fixing device 17 is attached. As described above, the CPU 26 determines whether or not the fixing device 17 is mounted based on a signal input to the P6 terminal via the pull-up resistor 39.

  If the CPU 26 determines in S802 that the fixing device 17 is installed, the CPU 26 performs type determination of the fixing device 17 in S803. As described above, if the resistor 58 is mounted in the fixing device 17, the CPU 26 determines that the fixing device is compatible with the 100V system. If the resistor 58 is not mounted, the CPU 26 is a fixing device compatible with the 200V system. Judge that there is. In S804, the CPU 26 stores the type discrimination result (also referred to as type information), which is information related to the type of the fixing device 17 determined in S803, in the RAM 26b serving as a storage unit. In S805, the CPU 26 clears the “no fixing device type information” information in the RAM 26b. On the other hand, if the CPU 26 determines in step S802 that the fixing device 17 is not installed, the CPU 26 stores “no fixing device type information” information in the RAM 26b in step S806.

(AC power supply voltage detection processing)
FIG. 6B is a flowchart showing a flow of voltage detection of the AC power supply 41 by the CPU 26 of this embodiment. The process of S811 is the same as the process of S801 in FIG. In S <b> 812, the CPU 26 performs voltage detection of the AC power supply 41 by the input voltage detection circuit 77. As described above, the CPU 26 detects the voltage of the AC voltage based on the AD conversion value obtained by AD converting the voltage input to the A / D port. The CPU 26 determines that the AC power supply 41 is a 200V system if the AD conversion value is larger than the threshold value 150 [dec], and determines that the AC power supply 41 is a 100V system if it is equal to or less than the threshold value 150 [dec]. In S813, the CPU 26 stores the result detected in S812 in the RAM 26b.

[Double voltage switching process]
FIG. 7 is a flowchart showing a flow of voltage doubler switching of the CPU 26 of this embodiment. FIG. 7 is a process executed after the type determination process of the fixing device 17 in FIG. 6A and the voltage detection process of the AC voltage in FIG. 6B are completed, and the power supply of the main body is already turned on. It is described on the assumption that In S <b> 821, the CPU 26 determines whether information “no fixing device type information” is stored in the RAM 26 b. If the CPU 26 determines in S821 that the information “no fixing device type information” is not stored in the RAM 26b, that is, if the fixing device 17 is installed, the process proceeds to S822. In S822, the CPU 26 confirms both the type discrimination result of the fixing device 17 stored in the RAM 26b and the voltage detection result of the AC power supply 41, and determines whether or not both the results indicate a 100V system. to decide. More specifically, the CPU 26 determines whether or not the fixing device 17 is a model that is compatible with a 100V AC power source and the detected AC voltage is a 100V system.

  In S822, if the CPU 26 determines that both the result of the type determination of the fixing device 17 and the result of the voltage detection of the AC power supply 41 indicate the 100V system, the process proceeds to S823. In S823, the CPU 26 turns on the relay 89 of the AC / DC converter 61 to switch the operation of the AC / DC converter 61 to voltage doubler control. On the other hand, if the CPU 26 cannot determine in step S822 that both the type determination result of the fixing device 17 and the voltage detection result of the AC power supply 41 indicate the 100 V system, the process proceeds to step S824. In addition, as a case of proceeding to the processing of S824, there are cases where both the result of the type determination of the fixing device 17 and the result of the voltage detection of the AC power supply 41 indicate the 200V system. In addition, the type determination result of the fixing device 17 may not match the voltage detection result of the AC power supply 41, that is, a mismatch may occur at 100V / 200V. In S821, the CPU 26 also proceeds to the processing of S824 when the information “no fixing device type information” is stored in the RAM 26b, that is, when the fixing device 17 is not attached to the main body. In S824, the CPU 26 does not turn on the relay 89 and does not switch the operation of the AC / DC converter 61 to voltage doubler control. It can be said that the CPU 26 switches the operation of the AC / DC converter 61 to full-wave rectification in S824. In S825, the CPU 26 turns on the triac 78 and activates the AC / DC converter 61. That is, supply of AC voltage to the AC / DC converter 61 is started.

  In this embodiment, as described in FIG. 7, the switching determination of the voltage doubler control is performed before starting the AC / DC converter 61 in S825. This is for reducing the risk of malfunction that occurs when the voltage doubler switching determination is continuously performed while detecting the voltage of the AC power supply 41 even after the AC / DC converter 61 is started.

  As described above, in the present embodiment, the switching determination of the double voltage is performed based on both the result of the voltage detection of the AC power supply 41 and the result of the type determination of the fixing device 17. For this reason, the robustness with respect to the erroneous detection of the voltage of AC power supply 41 can be improved, without complicating a circuit and raising a cost. As described above, according to the present embodiment, the universal power source can be simply configured, and the robustness can be enhanced while reducing the cost.

  In the first embodiment, when the fixing device 17 is not attached to the main body, the voltage doubler control is not performed regardless of the voltage detection result of the AC power supply 41 (S821 N and S824 in FIG. 7). In the present embodiment, the control is performed by storing the type information of the latest fixing device 17 that has been installed most recently among the fixing devices previously installed in the main body, in other words, in the nonvolatile memory 26c that is a storage unit. Is.

(Fixing device type discrimination processing)
Next, the flow of type determination and voltage doubler switching of the fixing device 17 of this embodiment will be described with reference to the flowchart of FIG. In addition, since the flow of the voltage detection of the alternating current power supply 41 of a present Example is the same as Example 1 demonstrated in FIG.6 (b), description is abbreviate | omitted. FIG. 8A is a flowchart showing the flow of the type determination of the fixing device 17 by the CPU 26 of this embodiment. Note that the processing in S801 to S805 in FIG. 8A is the same as that in FIG. In this embodiment, what is different from FIG. 6A is the processing of S906 and S907. If the CPU 26 determines in S802 that the fixing device 17 is not attached to the main body, it reads out the fixing device type information stored in the nonvolatile memory 26c in S906, and stores the read fixing device type information in the RAM 26b. (Data copy).

  Further, when the fixing device 17 is mounted on the main body, the CPU 26 performs the processing of S907 in addition to the processing of storing the type information that is the result of the type determination of the fixing device 17 in the RAM 26b in S804. That is, in S907, the CPU 26 further stores type information, which is a result of the type determination of the fixing device 17, in the nonvolatile memory 26c. By these processes, it is possible to use the latest type information of the fixing device in the fixing device mounted on the main body, in other words, the latest type information of the fixing device.

[Double voltage switching process]
FIG. 8B is a flowchart showing the flow of voltage doubler switching of the CPU 26 of this embodiment. FIG. 8B also shows the assumption that the power source of the main body is already turned on, as in the first embodiment. In the present embodiment, even when the fixing device 17 is not attached, type information of the fixing device that is most recently installed among the fixing devices that have been attached in the past is stored in the RAM 26b. For this reason, the determination process of S821 in FIG. 7 of the first embodiment is not performed in this embodiment. Further, the processing of S911 to S914 of the present embodiment is the same as the processing of S822 to S825 of FIG. Note that the type information of the fixing device referred to in S911 uses the latest information when the fixing device is attached when the fixing device is not attached.

  As described above, in this embodiment, the type information of the fixing device 17 mounted immediately before stored in the nonvolatile memory 26c is used for determination of the voltage doubler switching control. Thereby, even when the fixing device 17 is not attached to the main body, similarly to the first embodiment, robustness against erroneous detection of the voltage of the AC power supply 41 can be improved without increasing the complexity and cost of the circuit. it can. As described above, according to the present embodiment, the universal power source can be simply configured, and the robustness can be enhanced while reducing the cost.

  In the second embodiment, a configuration has been described in which the switching control of the double voltage control is possible by using the nonvolatile memory 26c even when the fixing device 17 is not mounted on the main body as in the first embodiment. In the present embodiment, a process when the fixing device 17 is not mounted on the main body and the type information of the fixing device 17 mounted immediately before is not stored in the nonvolatile memory 26c will be described.

(Fixing device type discrimination processing)
FIG. 9 is a flowchart showing the flow of the type determination of the fixing device 17 by the CPU 26 of this embodiment. The processing of S1001 to 1005 is the same as the processing of S801 to S804 and S907 in FIG. If the CPU 26 determines in S1002 that the fixing device 17 is not attached, it determines in S1007 whether or not the type information of the fixing device 17 is stored in the nonvolatile memory 26c. If the CPU 26 determines in S1007 that the type information of the fixing device 17 is stored in the nonvolatile memory 26c, the process proceeds to S1008. Note that the processing of S1008 is the same as the processing of S906 in FIG. After the processing of S1005 and S1008, in S1006, the CPU 26 clears the “no fixing device type information” information stored in the RAM 26b.

  If the CPU 26 determines in step S1007 that the type information of the fixing device 17 is not stored in the nonvolatile memory 26c, the process proceeds to step S1009. In S1009, the CPU 26 stores information “no fixing device type information” in the RAM 26b. In addition, since the process of the voltage detection of the alternating current power supply 41 and the process of voltage doubler switching of a present Example are the same as Example 1, description is abbreviate | omitted.

  As described above, in the present embodiment, when the fixing device 17 is not mounted and the type information of the fixing device 17 mounted immediately before is not stored in the nonvolatile memory 26c, the doubling is performed. Voltage control can be avoided. For this reason, similarly to the first embodiment, robustness against erroneous detection of the voltage of the AC power supply 41 can be enhanced without increasing the complexity of the circuit and increasing the cost. As described above, according to the present embodiment, the universal power source can be simply configured, and the robustness can be enhanced while reducing the cost.

  In the first to third embodiments, the switching power supply 27 is composed of two AC / DC converters 60 and 61. In the present embodiment, a case where the switching power supply 27 is constituted by one AC / DC converter will be described.

[Switching power supply]
(AC / DC converter)
FIG. 10A is a block diagram showing the configuration of the switching power supply 27 of the present embodiment. The AC / DC converter 90 which is the power supply circuit and the first conversion means generates a desired voltage Vm (> Vc) which is the first DC voltage, similarly to the AC / DC converter 61 shown in FIG. AC / DC converter. The AC / DC converter 90 has a voltage doubler switching circuit (relay 89) (see FIG. 4A). Furthermore, the AC / DC converter 90 has an input voltage detection circuit 77 similar to the AC / DC converter 60 shown in FIG. The DC / DC converter 91 as the second conversion means is configured to generate a desired voltage Vc that is a second DC voltage from the desired voltage Vm generated by the AC / DC converter 90. The configuration of the AC / DC converter 90 is based on the configuration in which the triac 78 and the drive circuit 79 are removed from the configuration of the AC / DC converter 61 in FIG. 77 (FIG. 3A). Therefore, detailed description of the circuit is omitted.

  In the present embodiment, when the AC voltage of the AC power supply 41 is supplied, the AC / DC converter 90 and the DC / DC converter 91 are activated in conjunction with each other. Further, the uses of the desired voltages Vm and Vc of the present embodiment are the same as the voltages Vm and Vcc of the first embodiment. In this embodiment, unless the AC / DC converter 90 having the voltage doubler switching circuit is activated, the voltage of the AC power supply 41 cannot be detected, and further, the type of the fixing device 17 cannot be determined by the CPU 26 using the desired voltage Vc as the power supply. For this reason, the determination of voltage doubler switching by the CPU 26 can be made only after the AC / DC converter 90 is activated.

  Further, when the AC / DC converter 90 does not perform voltage doubler switching when the AC power supply 41 is a 100 V system, the voltage Vp shown in FIG. That is, the load current value at which the desired voltage Vm can be continuously output is reduced as compared with the case where the AC / DC converter 90 is switched to voltage doubler control. For this reason, the desired voltage Vm cannot be continuously output with the consumption current consumed by the main body in the image forming operation (for example, the operation of an actuator such as a motor). However, if the current consumption is low enough to be consumed by the CPU 26 and its peripheral circuits (such as the type determination circuit of the fixing device 17), it is possible to continue outputting the desired voltage Vc.

[Double voltage switching process]
Next, the flow of voltage doubler switching according to this embodiment will be described with reference to the flowchart of FIG. Note that the flow of the voltage detection of the AC power supply 41 and the type determination of the fixing device 17 can be substituted by the processing described in the first to third embodiments, and thus description thereof is omitted here. Note that the processing in S1201 is the same as that in S801 in FIG. In S1202, the CPU 26 does not switch the operation of the AC / DC converter 90 to the voltage doubler control by not turning on the relay 89. In S1203, the CPU 26 executes the voltage detection process of the AC power supply 41 described in the first embodiment, and executes the type determination process of the fixing device 17 described in the first to third embodiments in S1204.

  In S1205, the CPU 26 determines whether or not both the type information of the fixing device 17 stored in the RAM 26b and the AC voltage of the AC power supply 41 indicate a 100V system. If the CPU 26 determines in S1205 that both the type information of the fixing device 17 and the AC voltage of the AC power supply 41 indicate the 100V system, the process proceeds to S1206. In S1206, the CPU 26 turns on the relay 89 to switch the operation of the AC / DC converter 90 to voltage doubler control. On the other hand, if the CPU 26 cannot determine in step S1205 that both the type information of the fixing device 17 and the AC voltage of the AC power supply 41 indicate the 100V system, the voltage doubler switching process ends. That is, when both the type information of the fixing device and the detection result of the voltage detection indicate the 200V system, or when the detection results do not coincide with each other at 100V / 200V, the CPU 26 determines the state of S1202, that is, the voltage doubler. Keep the state of not switching to control.

  As described above, in this embodiment, when the AC power supply 41 is a 100 V system, the voltage detection of the AC power supply 41 and the type determination of the fixing device 17 can be performed without switching the voltage doubler of the AC / DC converter 90. It can be carried out. In other words, even when the switching power supply 27 is composed of one AC / DC converter 90, it is doubled based on both the voltage detection result of the AC power supply 41 and the type determination result of the fixing device 17. A voltage switching determination process is performed. For this reason, the robustness with respect to the erroneous detection of the voltage of AC power supply 41 can be improved, without complicating a circuit and raising a cost. As described above, according to the present embodiment, the universal power source can be simply configured, and the robustness can be enhanced while reducing the cost.

  In the above-described embodiment, the 100V / 200V system is determined based on the type information of the fixing device. However, based on the type information of the device that is detachable and has a different compatible model in the 100V / 200V system. You may judge. In this case as well, the type determination is performed based on whether or not the resistor is mounted as in the fixing device.

17 Fixing Device 26 CPU
41 AC power supply 60, 61 AC / DC converter 77 Input voltage detection circuit

Claims (7)

A power supply circuit having a rectifying means for double-voltage rectification or full-wave rectification of the input AC voltage;
An unfixed toner image formed on the recording material by the image forming means is fixed on the recording material, and is a fixing means adapted to the first AC voltage, or a second voltage higher than the first AC voltage. a fixing unit that have a first storage means for storing information indicating which conforms fixing means into an AC voltage of,
An image forming apparatus comprising:
Voltage detecting means for detecting the AC voltage;
A type detecting means for detecting the type of the fixing means based on the information in the first storage means ;
The types in a case where the kinds compatible AC voltage detecting means and said fixing means Ri which is detected by the and said voltage AC voltage Ri which is detected by the detection means coincide, AC matched AC voltage the first When the voltage is a voltage, the rectifier is switched to the voltage doubler rectifier , and the AC voltage that matches the type of the fixing unit detected by the type detector and the AC voltage detected by the voltage detector do not match, And switching means for switching to the full-wave rectification when the matched AC voltage is the second AC voltage ;
An image forming apparatus comprising: A mounting detection means for detecting whether or not the fixing means is mounted;
The image forming apparatus according to claim 1, wherein the switching unit switches the rectifying unit to the full-wave rectification when the mounting detecting unit detects that the fixing unit is not mounted. . Mounting detection means for detecting whether or not the fixing means is mounted;
A second storage unit for storing information on the type of the fixing unit detected by the type detection unit;
With
The type detection unit, when the said fixing means by mounting detection means detects that it is not attached, detects the type of the fixing unit based on the second of the information stored in the storage means The image forming apparatus according to claim 1. 4. The image forming apparatus according to claim 3 , wherein the second storage unit stores information on the latest type of fixing unit among the fixing units attached to the image forming apparatus. First conversion means for converting the AC voltage into a first DC voltage;
The power supply circuit having the rectifying means, second converting means for converting the AC voltage into a second DC voltage;
With
The switching means is supplied with power from the first conversion means,
Said second conversion means, the type detection means and the the detection by the voltage detection means is performed, the type wherein the alternating current is detected by the matching AC voltage on the type of the fixing means detects said voltage detecting means by detecting means 2. The supply of the AC voltage is started after the switching means switches the rectifying means to the voltage doubler rectification or the full wave rectification based on whether or not the voltages match. The image forming apparatus according to claim 4 . The power supply circuit having the rectifying means, the first converting means for converting the AC voltage into a first DC voltage;
Second conversion means for converting the first DC voltage output from the first conversion means into a second DC voltage;
With
The switching means is supplied with power from the second conversion means, and after switching the rectifying means to the full-wave rectification, performs detection by the type detecting means and the voltage detecting means, and the type detecting means Switching the rectifying means to the voltage doubler rectification or the full-wave rectification based on whether or not the AC voltage suitable for the type of the fixing means detected by the DC voltage matches the AC voltage detected by the voltage detection means. The image forming apparatus according to claim 1, wherein the image forming apparatus is an image forming apparatus. The voltage detection means includes a diode, an inverting amplifier circuit, and a peak hold circuit,
The image forming apparatus according to claim 1, wherein a voltage corresponding to the AC voltage is output to the switching unit.

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