JP2007041271A - Image forming apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent an image forming apparatus including a separating protective means from causing image failures due to a member being left in off state of power source, by providing at a adoptable cost a power supply means that surely operates, even at power failure. <P>SOLUTION: The image forming apparatus has the separating protective means for preventing image failure, resulting from deformation in a member left in the OFF state of the power source, by including a power source OFF detection means for detecting turning off of a power source; a separating means for driving a separation member by an actuator and switching between contact and separation for fixing or transfer; and a separation control means for performing a separating operation, by starting the separation means when the turning off of the power source is detected. The image forming apparatus is provided with a charging means for accumulating electric power. The image forming apparatus is also provided with a power supply means, by which power is supplied from the charging means, when the separating operation of the separating protective means is carried out; and a means for preventing image failure, caused by a deformation in a member left in the OFF state of the power source after power failure, is provided at optimum cost and size in matching with the protective function, taking energy-saving into account. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an image forming apparatus, and more particularly to an image forming apparatus having a separation protection unit that drives a separation member and prevents image failure due to deformation of the member in a power-off state. It relates to a supply means.

  Conventionally, for example, as proposed in Patent Document 1 below, handshake control has been proposed in which a power-off operation is detected, a power-off sequence is activated to save a memory, and then the power is turned off. Yes.

  The power-off sequence also includes separation driving. The separation means that drives separation members such as fixing and transfer by an actuator and switches between contact and separation, and the separation means is activated when the power-off detection is detected by the power-off detection means. In addition, an image forming apparatus having a separation protection means for preventing image defects due to deformation of a member in a state where the power supply is turned off is disclosed by a separation control means for performing a separation operation.

  A conventional example of the present invention will be described below.

  FIG. 13 is an explanatory diagram illustrating the overall configuration of a conventional color laser beam printer.

  Reference numerals 1301, 1302, 1303, and 1304 denote laser scanners, which correspond to the respective colors Y, M, C, and Bk, and scan the laser beam in synchronization with the video signal.

  Reference numerals 1305, 1306, 1307, and 1308 denote photosensitive drums for each color, and the laser scanners 1301, 1302, 1303, and 1304 electrostatically scan the laser on the drum surfaces charged by the charging rollers 1309, 1310, 1311, and 1312. A latent image is formed and developed by developing rollers 1313, 1314, 1315, and 1316 to form a toner image.

  Reference numeral 1321 denotes a paper feed path. One sheet of media is picked up from the paper feed cassette 1322 by one rotation control of the paper feed roller 1323, transported in a state of being electrostatically attracted to the transfer belt 1324, and the transfer belt 1324 is sandwiched between them. By applying a transfer high voltage to the transfer rollers 1317, 1318, 1319, and 1320 facing each color photosensitive drum, the respective color toner images are sequentially transferred to form a full color toner image on the medium.

  Reference numeral 1325 denotes a heat fixing device, which is configured to fix a toner image on a medium to obtain a full color print.

  FIG. 14 is an explanatory diagram illustrating the configuration of the fixing / separating mechanism in the conventional color laser beam printer.

  Reference numeral 1401 denotes a contact state fixing device, and 1402 denotes a separated state fixing device.

  Reference numerals 1403 and 1404 denote fixing rollers, in which halogen heaters 1405 and 1406 are incorporated in a roller formed on a surface of a Teflon (registered trademark) resin material having releasability, and temperature control heating is performed by thermistors 1420 and 1421.

  Reference numerals 1407 and 1408 denote pressure rollers, which are formed of a Teflon (registered trademark) resin material having a releasability through a thick silicone rubber layer of about 3 mm, and contacted by pressure springs 1415 and 1416. Sometimes it is pressed by the fixing rollers 1403 and 1404 to form a fixing nip 1417.

  The pressure rollers 1407 and 1408 are connected to a driving source and rotate, whereby the medium 1419 on which the toner image is formed by the electrophotographic process is nipped and conveyed between the fixing roller and heat fixing is performed.

  The fixing nip 1417 forms a large nip width and secures a fixing property in a color printer having a larger toner load than a monochrome printer by selecting a material with low rubber hardness for the pressure roller and applying a large pressure. It is configured to be able to.

  Therefore, a separation mechanism is provided to prevent the rubber deformation of the pressure roller when the power is turned off for a long time such as when it is not used.

  Reference numerals 1409 and 1410 denote stepping motors, which drive the lift cams 1411 and 1412 with predetermined pulses, perform half-rotation control based on the phase positions of the photosensors 1413 and 1414 placed at the separated positions, and are separated or abutted like the separated portion 1418. A separation mechanism for switching to a separation state in which the pressure is released is configured.

  FIG. 15 is an explanatory diagram illustrating the configuration of a transfer separation mechanism in a conventional color laser beam printer.

  Reference numeral 1501 denotes a transfer roller contact state, and 1502 denotes a transfer roller separation state.

  Reference numerals 1507 and 1508 denote transfer rollers, which are formed by forming foamed rubber mainly composed of hydrin rubber containing carbon and having a predetermined resistance and hardness on a shaft with a thickness of about 3 mm.

  The transfer rollers 1507 and 1508 are pressed against the photosensitive drums 1503 and 1504 by sandwiching the transfer belts 1505 and 1506 with pressure springs 1515 and 1516 to form a transfer nip 1517, and the applied transfer high pressure is surely applied to the photosensitive drums 1503 and 1504. Thus, the toner image is surely transferred to the medium 1519.

  As with the fixing device, the transfer roller rubber is provided with a separation mechanism in order to prevent deformation when it is not used for a long time such as when the power is turned off.

  Reference numerals 1509 and 1510 denote stepping motors that drive the lift cams 1511 and 1512 with predetermined pulses, perform half-rotation control based on the phase positions of the photosensors 1513 and 1514 placed at the separated positions, and are separated or abutted like the separated portion 1518. A separation mechanism for switching to a separation state in which the pressure is released is configured.

  FIG. 12 is a block diagram illustrating a power supply configuration in a conventional color laser beam printer.

  A control CPU 1218 controls the actuator and the high voltage 1219 to perform sequence control of the entire printer.

  Reference numeral 1201 denotes a separation mechanism, which corresponds to the electrical configuration of the configuration described with reference to FIGS.

  A stepping motor 1202 is energized with a constant current by the stepping motor driver 1204 in response to a motor driver control signal 1206 from the control CPU 1218, and performs transfer separation driving based on the photosensor 1208.

  A stepping motor 1203 is energized with a constant current by the stepping motor driver 1205 in accordance with a motor driver control signal 1207 from the control CPU 1218 and performs fixing separation driving with reference to the photosensor 1209.

  Reference numeral 1220 denotes a low-voltage power supply unit, which includes a drive power supply 1212 insulated from the AC power supply 1211 and an insulating converter 1210 for generating a control power supply 1213 and a soft switch 1214 for realizing a power-off sequence when the power is turned off.

  The soft switch 1214 is an operation detection switch different from the hard switch that turns off the normal AC main current path. When the power is turned on, the soft switch 1214 issues a power start signal 1215 to start the insulation converter 1210, and when the power is off, the switch state signal 1217. Thus, the control CPU 1218 is notified that the power-off operation has been performed, and the handshake control is performed to stop the insulating converter 1210 by the power stop signal 1216 sent out after the control CPU 1218 finishes the separation drive control.

  FIG. 16 is a diagram illustrating the configuration of a low voltage power source in a conventional color laser beam printer.

  Reference numeral 1602 denotes a low-voltage power supply unit, which corresponds to the configuration of 1220 described with reference to FIG. 12, and supplies a DC24V drive power supply 1613 to the actuator and high voltage 1612 of the printer electrical equipment 1601 and a DC3.3V control power supply 1615 to the control CPU 1616.

  Filter 1604, rectifier bridge 1605, primary smoothing capacitor 1606, PWM oscillation IC 1607, FET 1608, insulation transformer 1609, primary auxiliary power supply 1620, rectifier 1610, voltage comparison unit 1611, and voltage feedback signal 1624 correspond to the insulation converter 1210 of FIG. A known switching power supply is configured, and an AC power supply 1603 is input to output DC24V as a drive power supply 1613.

  Reference numeral 1614 denotes a DC / DC converter, which lowers the DC 24V of the drive power supply 1613 to DC 3.3V by the step-down chopper control to constitute the control power supply 1213.

  Reference numeral 1621 denotes a soft switch corresponding to the soft switch 1214 in FIG. 12, which switches the start power supply 1618 generated by resistance voltage division and inputs the power start signal 1617 to the reset input of the oscillation stop latch 1619, and the PWM oscillation IC 1607. The isolation converter is started by starting the oscillation of. When the soft switch 1621 is turned off, the switch state signal 1622 is transmitted to the control CPU 1616 through the photocoupler, and when the separation drive control is finished, the power supply stop signal 1623 is received from the control CPU1616 and is input to the set input of the oscillation stop latch 1619 through the photocoupler. This stops the insulation converter.

As described above, in order to drive the fixing separation mechanism and the transfer separation mechanism apart when the power is turned off, the power supply unit is configured to maintain the power until the separation driving is finished after the power switch is turned off.
JP 2000-132244 A

  However, in the conventional example, since the driving power of the separation mechanism is supplied by the low-voltage power output, it is necessary to operate the low-voltage power supply even when the power is turned off, and wasteful power is consumed and the power cannot be reduced to 0 W when the power switch is turned off. There was a technical problem. In addition, there is a technical problem that the separation protection operation does not function because the low-voltage power output is reduced during a power failure.

  In addition, when an uninterruptible power supply is introduced as a measure against power failure, an uninterruptible power supply that is unrealistic in terms of size and cost is required as a protective measure to prevent image defects from the viewpoint of power capacity in order to supply power for the entire system. There was a problem.

  The present invention has been made paying attention to the above-described problems, and provides an image forming apparatus having a separation protection unit at a cost that can employ a power supply unit that operates reliably even during a power failure. The object is to prevent image defects due to neglect.

  In order to achieve the above object, the image forming apparatus has the following configurations (1) to (13).

(1) A power-off detection means for detecting power-off, a separation means for driving a separation member by an actuator to switch between contact and separation, the power-off detection means, and starting the separation means when detecting power-off, In an image forming apparatus having a separation protection unit that prevents image defects due to deformation of a member in a state where the power is turned off by a separation control unit that performs a separation operation.
Power storage means for storing electric power is provided, and power supply during power-off detection / separation operation of the separation protection means includes power supply means for performing power supply during the separation operation.

  (2) In the above (1), the separation member is a fixing unit that fixes and fixes a toner image by nipping and conveying the medium by a fixing roller and a pressure roller whose temperature is adjusted.

  (3) In the above (1), the separation member transfers the toner image by conveying the medium by pressure between a photoconductor that forms a toner image by an electrophotographic process and a transfer roller to which a predetermined potential is applied. It is a means.

  (4) In any one of the above (1) to (3), the power OFF detection means is configured by a soft switch detection means for detecting a power OFF manual operation with a switch.

  (5) In any one of the above (1) to (3), the power OFF detection means is constituted by a power failure detection means for detecting a power failure state.

  (6) In the above (5), the power failure detection means is constituted by AC current detection means for detecting and detecting that the AC input current falls below a predetermined level for a predetermined time.

  (7) In the above (5), the power failure detection means is constituted by zero cross voltage detection means for detecting and detecting the stop of the alternating voltage cycle of the AC input voltage.

  (8) In the above (5), the power failure detection means is constituted by a switching operation stop detection means for detecting and detecting a decrease in primary power source electromotive force of a low-voltage power supply.

  (9) In any one of the above (1) to (8), the power supply means is constituted by a power supply separation power supply means that supplies power from the power storage means to the separation protection means by a dedicated power line. Features.

  (10) In any one of the above (1) to (8), the power supply means includes a power supply cutoff means for cutting off power supply from the power storage means to other than the separation protection means, the power supply OFF detection means, and a power supply OFF The power supply interruption means is sometimes cut off, and the power supply from the power storage means is limited to the separation protection means.

  (11) In the above (10), the power supply interruption means is constituted by voltage interruption SW means for interrupting voltage application to the load.

  (12) In (10), the power supply interrupting means is constituted by an energization stopping means for interrupting energization of the load itself.

  (13) In any one of (10) to (12), the power OFF detection means includes both a power failure detection means and a soft switch detection means, and the power supply source to the separation protection means is a low voltage. The power supply path switching means for switching between the power supply and the power storage means when the power failure detection means is detected, and the power switch control means for switching to the low voltage power supply when the soft switch detection means is detected. Characterized by being preserved.

  According to the present invention, the power storage means is provided, and the power supply means for supplying the driving power of the separation means from the power storage means when the power is turned off is provided, so that the protection operation of the separation means is made to function even during a power failure. There is an effect of providing an image defect prevention means due to member deformation at an optimum cost and size corresponding to an optimum stored power capacity. In addition, it is possible to supply a printer with high energy-saving effect by providing technical means that can function even with a hard switch to reduce the power when the power is turned off to 0 W.

  The best mode for carrying out the present invention will be described below based on examples.

  The feature of the present invention resides in that the drive power of the separation means is supplied by the power storage means, and the power supply configuration will be described below with reference to a block diagram.

  FIG. 1 is a block diagram illustrating a power supply configuration in the color laser beam printer according to the first embodiment of the present invention.

  The block configuration diagram explaining the power supply configuration in the conventional example of FIG. 12 and the configuration having the same configuration and the same function are denoted by the same reference numerals and description thereof is omitted.

  Reference numeral 102 denotes power storage means, which receives electric power from a DC 24V drive power supply 1212, accumulates electric power, and outputs DC 24V.

  Reference numeral 101 denotes a separation control unit which inputs a 24V output from the power storage unit 102 as a driving power source.

  Reference numeral 103 denotes a sub CPU, which performs separation control using a voltage obtained by stepping down the 24V output from the power storage means 102 to 3.3V by the DC / DC converter 104. Reference numeral 106 denotes an on / off signal that turns on / off the insulating converter 1210 in accordance with the state of the soft switch 1214.

  Next, a detailed configuration of the power storage unit 102 will be described.

  FIG. 2 is an explanatory diagram illustrating the configuration of the power storage means in the color laser beam printer according to the first embodiment of the present invention.

  Reference numeral 201 denotes a power storage means, which corresponds to the power storage means 102 in FIG. 1, and includes an electric double layer capacitor 202 for storing power, a charging means 214 for charging, and a DC / DC converter 213 for converting the stored voltage to an output voltage. Consists of blocks.

  Two electric double layer capacitors 202 that store electricity are connected in series to form a power storage means having a charging completion voltage of 5V.

  Conventionally, the storage means is a secondary battery using an electrochemical reaction from the viewpoint of the storage capacity, and the capacitor is known from the viewpoint of the number of times of charge / discharge. In comparison with the above, an electric double layer capacitor having a remarkably large capacitance of several tens of F is selected.

  The charging means 214 of the present embodiment is constituted by a constant current charging circuit using chopper control in order to obtain a high conversion efficiency using a power source higher than the charging completion voltage.

  The charging unit 214 is a constant off-time chopping constant current circuit using a one-shot multivibrator 206. The charging unit 214 supplies a 24V power source to the power storage unit 202 through the FET 204 and the choke coil 203 which are SW units, and the charging current is supplied to the current detection resistor. The voltage is converted at 207, compared with the reference power source 209 by the comparator 208, and when the set peak current is reached, the gate of the one-shot multivibrator 206 is hit, the SW means 204 is turned off for a predetermined time, and the oscillation operation is performed by energizing again. It is composed.

  By the oscillation operation, the current itself charged in the choke coil 203 is turned on when turned on, and when turned off, the electric double layer capacitor 202 is charged with a constant current by returning from the ground through the return diode 205.

  In order to prevent overcharge, the hysteresis comparator 210 and the reference power supply 211 detect the voltage of the electric double layer capacitor 202. When the voltage reaches 5V, the set terminal of the one-shot multivibrator 206 is turned on to forcibly stop charging. Means.

  The DC / DC converter 213 is a chopper type boosting converter using a known choke coil, and boosts the voltage that changes to about 2 to 5 V to 24 V depending on the amount of electricity stored in the electric double layer capacitor 202.

  1 and 2 described above, the power supply means is configured so that when the soft switch 1214 is turned off, power can be supplied from the power storage means 102 and the separation operation can be performed even if the insulating converter is turned off. .

  A feature of the second embodiment of the present invention is that the power-off detection is detected by the power failure detection means, and the AC input can be directly turned off by the hard switch. The power supply configuration will be described below with reference to a block diagram.

  FIG. 3 is a block diagram illustrating a power supply configuration in the color laser beam printer according to the second embodiment of the present invention.

  The same configuration and the same function as the block configuration diagram illustrating the power supply configuration of the conventional example of FIG. 12 and the first embodiment of FIG.

  The configuration for supplying power from the power storage means 102 to the separation control means 101 is the same as that in the first embodiment, and a description thereof will be omitted.

  Reference numeral 301 denotes a low-voltage power supply unit. The power supply of the insulation converter 304 is turned on / off by the hard switch 302, and the power-off detection is performed by the power failure detection means 303 inserted between the insulation converter 304 and the hard switch 302. A signal 305 is sent to the sub CPU 103.

  Next, a specific configuration of the power failure detection unit 303 of the low voltage power supply unit 301 will be described.

  FIG. 4 is an explanatory diagram illustrating the configuration of the low-voltage power supply in the color laser beam printer according to the second embodiment of the present invention.

  The configuration having the same configuration and the same function as those of the configuration explanatory diagram for explaining the configuration of the low-voltage power supply in the conventional example of FIG.

  Reference numeral 401 denotes a low-voltage power supply unit, which corresponds to the low-voltage power supply unit 301 in FIG.

  Reference numeral 402 denotes a hard switch, which corresponds to the hard switch 302 in FIG.

  Reference numeral 403 denotes a power failure detection means, which corresponds to the power failure detection means 303 in FIG.

  Reference numeral 410 denotes a power failure detection signal, which corresponds to the power failure detection signal 305 in FIG.

  Reference numeral 404 denotes a current transformer, which is inserted between the filter 1604 and the rectifying bridge 1605 and converts an AC current waveform into a voltage waveform by a current detection resistor 405 connected to the secondary side. A rectifier bridge 406 rectifies the AC current waveform and converts the AC current waveform into a voltage value corresponding to the average current by the smoothing capacitor 407. Reference numeral 408 denotes a comparator, which outputs a power failure detection signal 410 when it is below a predetermined current level as compared with a reference power source 409 using a Zener diode.

  With the configuration of FIG. 4 described above, the power failure detection unit 303 of FIG. 3 is configured by the AC current detection unit that detects the interruption of the AC current for a predetermined time when the hard switch 402 is turned off, and the sub CPU separation control is activated. It is the one that has been shown.

  Although the power failure detection means 303 has been detected by the AC current detection means as described above, other means may be used, for example, the presence or absence of an AC voltage may be detected.

  The zero cross voltage detecting means will be described below.

  FIG. 5 is an explanatory diagram illustrating the configuration of the low-voltage power supply in the color laser beam printer according to the second embodiment of the present invention.

  The configuration having the same configuration and the same function as the configuration explanatory diagram for describing the configuration of the low-voltage power supply in the conventional example of FIG.

  Reference numeral 501 denotes a power failure detection means, which corresponds to the power failure detection signal 305 in FIG.

  The power failure detection unit 501 includes a positive voltage detection unit 502 and a negative voltage detection unit 503, and outputs a positive pulse 504 and a negative pulse 505 obtained by shaping the AC voltage of each polarity into a rectangular wave to the separation control unit 412.

  Next, a specific configuration of the positive voltage detection unit 502 will be described.

  FIG. 6 is an explanatory diagram illustrating the configuration of the power failure detection means in the color laser beam printer according to the second embodiment of the present invention.

  Reference numeral 601 denotes a power failure detection means, 602 denotes a positive voltage detection means, and 603 denotes a negative voltage detection means, which correspond to 501, 502, and 503 in FIG. 5, respectively.

  The positive voltage detection means 602 is input from the hot side of the AC line, and the negative voltage detection means 603 is input from the cold side of the AC line.

  Since the configuration of the negative voltage detection unit 603 is the same as that of the positive voltage detection unit 602, the description is omitted only for the positive voltage detection unit 602.

  Reference numeral 604 denotes a fast recovery diode that rectifies the AC voltage by half-wave, divides the voltage by the voltage dividing resistors 605 and 606 and the voltage dividing resistor 607, and compresses the voltage amplitude to a voltage that can be input by the transistor 609. The capacitor 608 removes noise. The transistor 609 switches the half-wave rectified waveform at a predetermined level near 0 V, and supplies the shaped waveform to the secondary side voltage conversion resistor 611 through the photocoupler 610 and outputs it as a positive pulse 612. Similarly, the negative voltage detection means 603 outputs a negative pulse 613 having a phase difference of 180 degrees.

  The separation control unit alternately monitors the positive pulse 612 and the negative pulse 613, and recognizes a power failure state when no pulse is generated at a predetermined timing.

  With these configurations, the separation protection unit is configured so that the separation control unit can be activated and the separation operation can be performed not only when the switch is turned off but also when a power failure occurs.

  A feature of the third embodiment of the present invention is that, as a power feeding method to the separation control means of the power storage means power when the power is turned off, a power supply cutoff means for cutting power supply from the power storage means to other than the separation protection means is provided. The power supply cut-off means is cut off, and a power supply path limiting power supply means for limiting the power supply from the power storage means to the separation protection means is provided.

  An example of the power supply configuration will be described below.

  FIG. 7 is a block diagram illustrating a power supply configuration in the color laser beam printer according to the third embodiment of the present invention.

  The same configuration and the same function as the block configuration diagram for explaining the power feeding configuration of the conventional example of FIG. 12 and the first and second embodiments of FIG.

  Reference numeral 701 denotes separation control means, which outputs a power supply cutoff signal 704 to the power supply cutoff means 703 from the sub CPU 702 that performs separation control.

  The power cut-off means 703 is a switch means inserted in the path of the driving power source of the actuator 105 including the 24V output of the power storage means 102 and the high-voltage power supply other than the separation means. Although described as a relay in FIG. As long as it has a blocking characteristic.

  When the sub CPU 702 detects a power failure detection signal from the power failure detection means 303, the power supply path is limited so that the stored power of the power storage means 102 is supplied only to the separation means by starting the separation control and simultaneously shutting off the power supply interruption means 703. The power supply means is taken.

  In this example, the interruption control of the power supply interruption means 703 is performed by the power failure detection signal of the power failure detection means 303 via the secondary side sub CPU 702, but is directly controlled by the output of the primary side power failure detection means. There may be.

  FIG. 8 is a block diagram illustrating a power supply configuration in the color laser beam printer according to the third embodiment of the present invention.

  Configurations having the same configuration and function as those in the block configuration diagram illustrating the power feeding configuration of the conventional example of FIG. 12 and the first and second embodiments of FIG.

  Reference numeral 801 denotes a cut-off relay that is directly driven by a primary auxiliary power supply 803 that is a detection output of the power failure detection means 802.

  Next, the specific configuration of the power failure detection means 802 of the low-voltage power supply unit 804 and the merit of providing the power supply path limited power supply means to supply the stored power only to the separation means via the power supply cutoff means 703 in the third embodiment. Will be explained.

  FIG. 9 is an explanatory diagram illustrating the configuration of the low-voltage power supply in the color laser beam printer according to the third embodiment of the present invention.

  Configurations having the same configuration and function as those of the configuration explanatory diagram for explaining the configuration of the low voltage power source in the conventional example and the embodiment of FIG.

  Reference numeral 901 denotes a low-voltage power supply unit, which corresponds to the low-voltage power supply unit 804 in FIG.

  Reference numeral 902 denotes a cutoff relay, which is driven by a primary auxiliary power source 903.

  The interruption relay 902 is connected to a 24V output from the power storage means 411 at a contact, and outputs a drive power supply 904 for an actuator including a high-voltage power supply from the other contact.

  Reference numeral 905 denotes a power failure detection signal, which activates the separation control means by monitoring the cutoff output of the drive power source 904.

  As described above, the power failure detection means is configured without the addition of a special power failure detection circuit by the switching operation stop detection means that detects and detects the primary power supply drop of the low-voltage power supply.

  7 and 8, the power supply means is provided with a power cut-off means for cutting off the power supply from the power storage means to other than the separation protection means, and cuts off the power supply cut-off means when the power is turned off. By providing the power supply path limited power supply means for limiting the power supply from the means to the separation protection means, the drive voltage of the low-voltage power supply is supplied by supplying all the drive power via the power storage means as shown in FIG. It is possible to reduce the accuracy, the control power supply is configured with a plurality of winding outputs of the isolation transformer 906, voltage feedback control is performed with 3.3V output, and the drive power supply is configured with no feedback of only the rectifier 907. This eliminates the need for a DC / DC converter for the control power supply and has an advantage that a low-voltage power supply can be configured at low cost.

[Other Examples]
As described above, the present invention is provided with the power storage means and the power supply means for supplying the driving power of the separation mechanism by the power storage means.

  In the first to third embodiments, the example in which the power of the power storage means is used exclusively for driving the separation mechanism has been described. However, in this patent, the power supply means supplies power to the separation mechanism from the power storage means when the power is turned off. However, it is not intended to limit the power usage of the power storage means when the power is turned on. Therefore, it may be used in combination with the function of supplying the power of the power storage means to another driving load when the power is turned on. For example, the power of the power storage means may be supplied to another driving load when the starting power is insufficient immediately after the power is turned on, and used in combination with a function of suppressing AC input power.

  An example of a power supply configuration that is an embodiment of the present invention will be described below.

  FIG. 10 is a block diagram illustrating a power supply configuration in a color laser beam printer according to another embodiment of the present invention.

  The same configurations and the same functions as those in the conventional configuration of FIG. 12 and the block configuration diagram illustrating the power supply configurations of the first to third embodiments are denoted by the same reference numerals, and description thereof is omitted.

  Reference numeral 1001 denotes a separation control unit, and the control is performed by the control CPU 1002, and the control power is converted to 3.3V from the 24V output of the same power storage unit as the drive power by the DC / DC converter 104 to obtain the power. The control CPU 1002 also controls a control object other than the separation means by a control signal 1005. In the present embodiment, the driving power source of the driving load other than the separating means is divided into two systems.

  Reference numeral 1003 denotes a driving power source 1 which supplies a 24V output of a low voltage power source including a driver to a driving load 1 of 1007 including a drum motor, a paper feed motor, and a high voltage power source.

  Reference numeral 1004 denotes a driving power source 2 which supplies the 24V output of the power storage means 102 to a driving load 2 of 1008 including a fixing motor and a scanner motor including a driver.

  The driving load 2 (1008) is a load in which the energization periods overlap in the warm-up energization section of the engine fixing unit immediately after the power is turned on. In this embodiment, the temperature is adjusted during the fixing unit warm-up. Therefore, a fixing motor that rotates idly and a scanner motor that has a relatively long start-up time and a load approximately 10 times higher than that in a steady state are selected.

  With the power supply configuration in which the driving load 2 (1008) is supplied from the power storage unit 102, power is supplied from the power storage unit 102 to the lack of starting power with respect to the AC input current standard in the warm-up energizing section of the fixing device immediately after the power is turned on. By doing so, the AC input current is suppressed.

  Reference numeral 1006 denotes an energization off signal, which is connected to the drivers of the drive load 1 (1007) and the drive load 2 (1008). When a power failure detection signal is received when the power is turned off, the energization of the driver of the drive load excluding the separation means is cut off. It was made to act.

  The power cut-off means of these drivers is constituted by a power supply path limited power supply means that limits power supply from the power storage means to the separation protection means when the power is turned off.

  In this embodiment, the power source of the driving load 1 (1007) is supplied from a low-voltage power source. However, any driving load can be used as long as the power source is limited from the power storage unit when the power source is turned off. The power may be supplied via the power storage means 102.

  In the above embodiment, the power supply from the power storage means to the separation means is performed at the time of power-off operation or at the time of a power failure.

  FIG. 11 is a block diagram illustrating a power supply configuration in a color laser beam printer according to another embodiment of the present invention.

  The same configurations and the same functions as those in the conventional configuration of FIG. 12 and the block configuration diagram illustrating the power supply configurations of the first to third embodiments are denoted by the same reference numerals, and description thereof is omitted.

  Reference numeral 1101 denotes a switching relay configured to switch the driving power of the separation unit 1201 from the power storage unit 102 and the insulating converter by a selection signal from the control CPU 1104.

  Reference numeral 1102 denotes a low-voltage power supply unit, which has both a power failure detection means 303 and a soft switch 1214.

  In the event of a power failure, the control CPU 1104 employs a control means to switch the switching relay 1101 to the power storage means 102 by the input of a power failure detection signal 1103 and to switch to an insulating converter when the soft switch 1214 is off.

  With the above configuration, when the power switch is normally turned off, the stored power for suppressing the AC input current when the power is on as described in the above embodiment can be preserved by supplying the separation drive power from the isolation converter. There is.

1 is a block diagram illustrating a power supply configuration in a color laser beam printer according to a first embodiment of the present invention. Structure explanatory drawing explaining the structure of the electrical storage means in the color laser beam printer of Example 1 of this invention FIG. 5 is a block diagram illustrating a power supply configuration in a color laser beam printer according to a second embodiment of the present invention. Structure explanatory drawing explaining the structure of the low voltage | pressure power supply in the color laser beam printer of Example 2 of this invention Structure explanatory drawing explaining the structure of the low voltage | pressure power supply in the color laser beam printer of Example 2 of this invention Structure explanatory drawing explaining the structure of the power failure detection means in the color laser beam printer of Example 2 of this invention Block configuration diagram for explaining a power supply configuration in the color laser beam printer according to the third embodiment of the present invention. Block configuration diagram for explaining a power supply configuration in the color laser beam printer according to the third embodiment of the present invention. Structure explanatory drawing explaining the structure of the low voltage | pressure power supply in the color laser beam printer of Example 3 of this invention The block block diagram explaining the electric power feeding structure in the color laser beam printer of the other Example of this invention The block block diagram explaining the electric power feeding structure in the color laser beam printer of the other Example of this invention Block configuration diagram for explaining a power supply configuration in a conventional color laser beam printer Configuration explanatory diagram illustrating the overall configuration of a conventional color laser beam printer Structure explanatory drawing explaining the structure of the fixing separation mechanism in the conventional color laser beam printer Configuration explanatory diagram illustrating the configuration of a transfer separation mechanism in a conventional color laser beam printer Configuration explanatory diagram for explaining the configuration of a low-voltage power source in a conventional color laser beam printer

Explanation of symbols

101 Separation control means 102 Power storage means 103 Sub CPU
104 DC / DC converter 105 Actuator, high-voltage power supply 201 Power storage means 202 Electric double layer capacitor, power storage means 203 Choke coil 204 FET, SW means 205 Free-wheeling diode 206 One-shot multivibrator 207 Current detection resistor 208 Comparator 209 Reference power supply 210 Hysteresis comparator 211 Reference power supply 212 OR gate 213 DC / DC converter 214 Charging means 301 Low voltage power supply unit 302 Hard switch 303 Power failure detection means 304 Insulation converter 305 Power failure detection signal 401 Low voltage power supply unit 402 Hard switch 403 Power failure detection means 404 Current transformer 405 Current detection resistor 406 Rectifier bridge 407 Smoothing capacitor 408 Comparator 409 Reference power supply 410 Power failure detection signal 501 Power failure detection means 502 Positive voltage detection means 503 Negative voltage detection means 504 Positive pulse 505 Negative pulse 601 Power failure detection means 602 Positive voltage detection means 603 Negative voltage detection means 604 Fast recovery diode 605 Voltage dividing resistor 606 Voltage dividing resistor 607 Voltage dividing resistor 608 Capacitor 609 Transistor 610 Photocoupler 611 Voltage conversion resistor 612 Positive pulse 613 Negative pulse 701 Separation control means 702 Sub CPU
703 Power cut-off means 704 Power cut-off signal 801 Cut-off relay 802 Power failure detection means 803 Primary auxiliary power supply 804 Low-voltage power supply unit 901 Low-voltage power supply unit 902 Cut-off relay 903 Primary auxiliary power supply 904 Drive power supply 905 Power failure detection signal 906 Insulation transformer 907 Rectifier 1001 Separation control means 1002 Control CPU
1003 Drive power supply 1
1004 Drive power supply 2
1005 Control signal 1006 Energization off signal 1007 Drive load 1
1008 Drive load 2
1101 Switching relay 1102 Low voltage power supply unit 1103 Power failure detection signal 1104 Control CPU
1201 Separation mechanism, separation means 1202 Stepping motor 1203 Stepping motor 1204 Stepping motor driver 1205 Stepping motor driver 1206 Motor driver control signal 1207 Motor driver control signal 1208 Photosensor 1209 Photosensor 1210 Insulation converter 1211 AC power supply 1212 Drive power supply 1213 Control power supply 1214 Software Switch 1215 Power supply start signal 1216 Power supply stop signal 1217 Switch status signal 1218 Control CPU
1219 Actuator, High Voltage 1220 Low Voltage Power Supply Unit 1301 Laser Scanner 1302 Laser Scanner 1303 Laser Scanner 1304 Laser Scanner 1305 Photosensitive Drum 1306 Photosensitive Drum 1307 Photosensitive Drum 1308 Photosensitive Drum 1309 Charging Roller 1310 Charging Roller 1311 Charging Roller 1312 Charging Roller 1313 Developing Roller 1314 Developing Roller 1315 Developing roller 1316 Developing roller 1317 Transfer roller 1318 Transfer roller 1319 Transfer roller 1320 Transfer roller 1321 Paper feed path 1322 Paper feed cassette 1323 Paper feed roller 1324 Transfer belt 1325 Fixing device 1401 Contact state fixing device 1402 Separated state fixing device 1403 Fixing roller 1404 Fixing roller 1405 Halogen heater 1406 Halogen heater 1407 Pressure roller 1408 Pressure roller 1409 Stepping motor 1410 Stepping motor 1411 Lift cam 1412 Lift cam 1413 Photo sensor 1414 Photo sensor 1415 Pressure spring 1416 Pressure spring 1417 Fixing nip 1418 Separating portion 1419 Media 1420 Thermistor 1421 Thermistor 1501 Transfer roller contact state 1502 Transfer roller separation state 1503 Photosensitive drum 1504 Photosensitive drum 1505 Transfer belt 1506 Transfer belt 1507 Transfer roller 1508 Transfer roller 1509 Stepping motor 1510 Stepping motor 1511 Lift cam 1512 Lift cam 1513 Photo sensor 1514 Photo sensor 1515 Pressure spring 1516 Pressure spring 1517 Transfer nip 1518 Separation part 1519 Media 16 1 printer electric 1602 low voltage power supply unit 1603 AC power 1604 filter 1605 rectifier bridge 1606 primary smoothing capacitor 1607 PWM oscillation IC
1608 FET
1609 Isolation transformer 1610 Rectifier 1611 Voltage comparison unit 1612 Actuator 1613 Drive power supply 1614 DC / DC converter 1615 Control power supply 1616 Control CPU
1617 Power supply start signal 1618 Start power supply 1619 Oscillation stop latch 1620 Primary auxiliary power supply 1621 Soft switch 1622 Switch status signal 1623 Power supply stop signal 1624 Voltage feedback signal

Claims (13)

A power OFF detection means for detecting power OFF, a separation means for driving a separation member by an actuator to switch between contact and separation, the power OFF detection means, and the separation means are activated when the power OFF is detected, and the separation operation is performed. In the image forming apparatus having the separation protection means for preventing the image defect due to the deformation of the member in the state where the power is turned off by the separation control means to perform,
An image forming apparatus comprising: a power storage unit that stores electric power; and a power supply unit that performs power supply during the power-off detection and separation operation of the separation protection unit by the power storage unit.   The image forming apparatus according to claim 1, wherein the separation member is a fixing unit that fixes and fixes a toner image by sandwiching and conveying a medium by a fixing roller and a pressure roller that are adjusted in temperature.   The separation member is transfer means for transferring a toner image by sandwiching and conveying a medium by a photosensitive member that forms a toner image by an electrophotographic process and a transfer roller to which a predetermined potential is applied. Item 2. The image forming apparatus according to Item 1.   4. The image forming apparatus according to claim 1, wherein the power-off detection unit includes a soft switch detection unit that detects a power-off manual operation with a switch.   The image forming apparatus according to any one of claims 1 to 3, wherein the power OFF detection means is constituted by a power failure detection means for detecting a power failure state.   6. The image forming apparatus according to claim 5, wherein the power failure detection means comprises AC current detection means for detecting and detecting that the AC input current falls below a predetermined level for a predetermined time.   6. The image forming apparatus according to claim 5, wherein the power failure detection means comprises zero cross voltage detection means for detecting and detecting a stop of an alternating voltage cycle of the AC input voltage.   6. The image forming apparatus according to claim 5, wherein the power failure detection means is constituted by a switching operation stop detection means for detecting and detecting a decrease in primary power source electromotive force of a low-voltage power supply.   9. The image forming apparatus according to claim 1, wherein the power supply unit includes a power supply separation power supply unit that supplies power from the power storage unit to the separation protection unit using a dedicated power line. .   The power supply means shuts off the power supply from the power storage means to other than the separation protection means, the power supply OFF detection means, shuts off the power supply cutoff means when the power is OFF, and supplies power from the power storage means. 9. The image forming apparatus according to claim 1, wherein the image forming apparatus is configured by a power supply path limited power supply unit limited to the separation protection unit.   The image forming apparatus according to claim 10, wherein the power supply cutoff unit includes a voltage cutoff SW unit that cuts off voltage application to a load.   The image forming apparatus according to claim 10, wherein the power supply interrupting unit includes an energization stopping unit that interrupts energization of the load itself.   The power OFF detection means includes both a power failure detection means and a soft switch detection means, a power supply path switching means for switching a power supply source to the separation protection means between a power storage means and a low voltage power source, and when a power failure detection means is detected. 13. The storage power is preserved during normal operation of the soft switch OFF by switching to the storage means and switching to the low voltage power source when the soft switch detection means is detected. Image forming apparatus.

Images