JP2014217102A - Power supply device and image forming apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce a risk that mismatching occurs in operations between load circuits when the supply of an external voltage is interrupted and then resumed.SOLUTION: A power supply device 90 includes: first/second power supply parts 91/92 which generate first/second power supply voltages by using an external voltage; a detection part 12 which detects the supply/interruption of the external voltage; a first load part 14 having capacitive loads 14-1 to 14-m, and operates by using the first power supply voltage; a second load part 24 having capacitive loads 24-1 to 24-n which is capable of storing power smaller than power which can be stored in the first load part 14, and operates by using the second power supply voltage; and a reset control part 13 which operates by using the first power supply voltage, and resets the second load 24, and then resets the first load part 14 when the interruption of the external voltage is still detected after the lapse of a predetermined time in which the second load part 24 is operable with power stored in the capacitive loads of the second load part 24 since the interruption of the external voltage is detected.

Description

  The present invention relates to a power supply device that generates a plurality of power supply voltages using an external voltage and an image forming apparatus including the power supply device, and more particularly to a technique for resetting a plurality of load units that operate using each power supply voltage.

  Conventionally, when a short circuit and / or disconnection of a load circuit is detected by monitoring a current supplied to the load circuit, for example, as described in Patent Document 1 below, a short circuit and / or disconnection of the load circuit is detected. In addition, a power supply device that cuts off the supply of power to a load circuit is known. In addition, a power supply device having a plurality of load circuits is provided with a plurality of power supply units that generate different power supply voltages using external voltages supplied from an external power supply such as a commercial AC power supply. A technique is known in which a power supply unit for supplying a power supply voltage to each load circuit is made different in accordance with the required power supply voltage.

  In such a power supply device, when the supply of external voltage is momentarily interrupted (instantaneous interruption) due to unstable power supply from an external power supply or a lightning strike in emerging countries, each power supply unit Since the voltage cannot be supplied, each load circuit operates for a while using the electric power stored in the capacitive load of each load circuit, and then stops operating. For this reason, a load circuit having a capacitive load with a small amount of electric power that can be stored stops operation earlier.

JP-A-9-70133

  However, when the supply of external voltage is restarted in the situation where only some load circuits have stopped operating due to the momentary interruption of the external voltage supply, the part of the load circuits that have stopped operating When the power supply voltage is supplied again, the operation is resumed, and some of the load circuits are once reset, but the load circuit that has not stopped operating at the momentary interruption Operation will be continued before and after disconnection, and it has not been reset. As a result, there is a possibility that an operation mismatch occurs between the load circuits.

  The present invention has been made to solve the above-described problem. When the supply of the external voltage is resumed after the supply of the external voltage is interrupted, an operation mismatch occurs between the load circuits. It is an object of the present invention to provide a power supply device that can reduce the risk of occurrence and an image forming apparatus including the power supply device.

  The power supply apparatus according to the present invention includes a first power supply unit that generates a predetermined first power supply voltage using an external voltage, and a second power supply that generates a second power supply voltage smaller than the first power supply voltage using the external voltage. A power supply unit; a detection unit that detects supply and interruption of the external voltage; a capacitive load capable of storing predetermined power; and a first load unit that operates using the first power supply voltage; A capacitive load capable of storing less than the power that can be stored in one load unit; a second load unit that operates using the second power supply voltage; and an operation using the first power supply voltage; When the interruption of the external voltage is detected by the detection unit, the time during which the second load unit can be operated with the electric power stored in the capacitive load of the second load unit from the detection point of the interruption When a predetermined first time limit has passed, When the serial detection unit remains of interruption of the external voltage is detected, after resetting the second load portion, and a reset control unit to reset the first load portion.

  According to this configuration, when the detection unit detects the interruption of the external voltage, the first time limit elapses from the detection time of the interruption, that is, the second load unit is the electric power stored in the capacitive load. When it is considered that the operation can no longer be performed, and the detection of the external voltage is still detected by the detection unit, the first load unit is reset after the second load unit is reset. For this reason, when the interruption of the external voltage is detected by the detection unit, both the first load unit and the second load unit are in a reset state, and then the supply of the external voltage is resumed. In addition, it is possible to reduce the possibility of inconsistency in operation between the first load unit and the second load unit.

  In addition, the reset control unit may operate the first load unit with electric power stored in the capacitive load of the first load unit from the detection time of the interruption after resetting the second load unit. When the supply is detected by the detection unit before the second time limit that is predetermined as a possible time elapses, it is preferable that the first load unit is reset after the supply is detected.

  After resetting the second load unit, it is considered that the first load unit is operating with the electric power stored in the capacitive load until the second time limit elapses after the detection of the interruption of the supply of the external voltage. When the first load unit is reset without detecting the supply of the external voltage by the detection unit, the power necessary for resetting the first load unit is not supplied and the first load unit is normally reset. There is a possibility that it cannot be done.

  However, according to this configuration, after the second load unit is reset, the first load unit is stored in the capacitive load until the second time limit elapses after the detection of the external voltage supply interruption. When the supply of the external voltage is detected when it is considered that the operation is performed with the electric power, the first load unit is reset after the supply of the external voltage is detected. Therefore, the first load unit can be reliably reset in a state where the first power supply voltage is supplied from the first power supply unit to the first load unit by supplying the external voltage. As a result, when the supply of the external voltage is resumed, the first load unit and the second load unit are both reset, and an operation mismatch occurs between the first load unit and the second load unit. The fear can be reduced.

  In addition, the reset control unit may operate the first load unit with electric power stored in the capacitive load of the first load unit from the detection time of the interruption after resetting the second load unit. When the supply is detected by the detection unit before the second time limit that is predetermined as a possible time elapses, the first time limit is reached when the second time limit elapses from the detection time of the interruption. It is preferable to reset the load section.

  After the second load part is reset, when the supply of the external voltage is detected from the time when the interruption of the external voltage is detected until the second time limit elapses, that is, the first load part becomes a capacitive load. When the supply of external voltage is detected when the stored power is considered to be operating, when the second time limit has elapsed since the detection of the external voltage interruption, the first power supply unit The first power supply voltage is supplied to one load unit.

  In other words, according to this configuration, the first load unit is reset when the second time limit has elapsed from the time when the external voltage is detected to be cut off. The first load unit can be reliably reset in a state where the voltage is supplied. As a result, when the supply of the external voltage is resumed, the first load unit and the second load unit are both reset, and an operation mismatch occurs between the first load unit and the second load unit. The fear can be reduced.

  Alternatively, the reset control unit preferably resets the first load unit when the supply is detected by the detection unit after resetting the second load unit.

  According to this configuration, since the first load unit is reset when the supply of the external voltage is detected after the second load unit is reset, the first load unit is detected from the time when the interruption of the external voltage is detected. The first load unit can be quickly reset without waiting until a time when the load unit is considered to be unable to operate with the power stored in the capacitive load. As a result, when the supply of the external voltage is resumed, the first load unit and the second load unit are both reset, and an operation mismatch occurs between the first load unit and the second load unit. The fear can be reduced.

  Further, it is preferable that the external voltage is an AC voltage, and the detection unit detects supply and interruption of the external voltage based on a zero cross point of the AC voltage.

  According to this configuration, it is possible to easily detect the supply and cut-off of the external voltage using a known technique of detecting the supply and cut-off of the AC voltage based on the zero cross point of the AC voltage.

  The image forming apparatus according to the present invention includes the power supply device, and the first load unit includes an image forming unit that forms an image on a sheet.

  According to this configuration, in the image forming apparatus, when the supply of the external voltage is resumed after the supply of the external voltage is interrupted, both the first load unit and the second load unit are reset. Therefore, it is possible to reduce the possibility of inconsistency in operation between the image forming unit and the second load unit included in the first load unit.

  According to the present invention, when the supply of the external voltage is restarted after the supply of the external voltage is interrupted, the power supply apparatus capable of reducing the possibility of causing inconsistency in operation among the load circuits and An image forming apparatus including the power supply device can be provided.

1 is a schematic structural diagram of a printer according to an embodiment of an image forming apparatus of the present invention. It is a block diagram which shows the electric constitution of the power supply device which concerns on one Embodiment of the power supply device of this invention. It is a timing chart which shows the operation | movement which a reset control part resets a 1st load part and a 2nd load part.

  Hereinafter, a printer 1 according to an embodiment of an image forming apparatus of the present invention will be described with reference to the drawings. In this embodiment, the printer 1 is described as an example of the image forming apparatus. However, the image forming apparatus may be a copier, a facsimile machine, or a multifunction machine having a plurality of these functions. FIG. 1 is a schematic structural diagram of a printer 1 according to an embodiment of an image forming apparatus of the present invention. As shown in FIG. 1, the printer 1 includes an image forming unit 80, a fixing unit 70, and an operation unit 50.

  The image forming unit 80 includes a photosensitive drum 81, a charger 82, an exposure device 83, a developing device 84, and a transfer roller 85.

  The photosensitive drum 81 is a cylindrical member having a long main scanning direction (front and back direction in FIG. 1), and rotates in a clockwise direction in FIG. 1 in response to a driving force from a motor (not shown). To do. The charger 82 charges the surface of the photosensitive drum 81 substantially uniformly.

  The exposure device 83 includes a light source such as a laser diode. The exposure device 83 irradiates the peripheral surface of the photosensitive drum 81 that is substantially uniformly charged by the charger 82 with an optical signal corresponding to the image data. An electrostatic latent image is formed. The image data is acquired, for example, by receiving image data transmitted from an external device such as a personal computer connected to the printer 1 via a network using a network interface circuit (not shown).

  The developing device 84 includes a toner container for storing toner, and generates a potential difference between the photosensitive drum 81 and the developing device 84 by applying a developing bias voltage, thereby forming a photosensitive film on which an electrostatic latent image is formed. Toner is supplied to the surface of the body drum 81 to form a toner image. The transfer roller 85 is disposed at a position facing the photosensitive drum 81. The transfer roller 85 transfers the toner image formed on the photoconductive drum 81 onto the paper conveyed along the conveyance path P.

  The fixing unit 70 includes a fixing roller 700 containing a heater and the like, and a pressure roller 701 provided at a position facing the fixing roller 700, and is formed on the sheet by heating and conveying the sheet on which the toner image is formed. Fix the toner image. Note that the pressure roller 701 rotates by receiving a driving force from a motor (not shown), and the fixing roller 700 rotates following the rotation of the pressure roller 701.

  The operation unit 50 includes a display unit 51 for displaying information and an operation key unit 52 for allowing a user to perform various instruction operations. The display unit 51 is, for example, a liquid crystal display having a touch panel function, and displays various types of information. The operation key unit 52 includes various keys such as a start key for a user to input a print execution instruction and a numeric keypad for inputting the number of copies to be printed.

  Next, an image forming operation by the image forming unit 80 will be briefly described. First, the charger 82 charges the surface of the photosensitive drum 81 substantially uniformly. Then, the surface of the charged photosensitive drum 81 is exposed by the exposure device 83, and an electrostatic latent image of an image to be formed on the paper is formed on the surface of the photosensitive drum 81. The electrostatic latent image is developed by attaching toner to the surface of the photosensitive drum 81 by the developing device 84, and the toner image on the surface of the photosensitive drum 81 is transferred to the paper by the transfer roller 85. After the image forming operation by the image forming unit 80 is performed, the toner image transferred onto the paper is fixed by the fixing unit 70.

  The printer 1 includes a power supply device 90 inside the housing. FIG. 2 is a block diagram showing an electrical configuration of the power supply apparatus 90 according to the embodiment of the power supply apparatus of the present invention.

  As shown in FIG. 2, the power supply device 90 includes a commercial AC power supply AC, a first power supply unit 91, a second power supply unit 92, a first system unit 10, and a second system unit 20. .

  The commercial AC power supply AC supplies a commercial AC voltage (external voltage) to the first power supply unit 91 and the second power supply unit 92.

  The first power supply unit 91 includes an AC / DC converter (not shown) inside, and generates a DC voltage of a predetermined magnitude using the commercial AC voltage supplied from the commercial AC power supply AC. Hereinafter, the DC voltage generated by the first power supply unit 91 is referred to as a first power supply voltage V1.

  The second power supply unit 92 includes an AC / DC converter (not shown) inside, and generates a DC voltage smaller than the first power supply voltage V1 using a commercial AC voltage supplied from the commercial AC power supply AC. Hereinafter, the DC voltage generated by the second power supply unit 92 is referred to as a second power supply voltage V2.

  The first system unit 10 operates in response to the supply of the first power supply voltage V <b> 1 generated by the first power supply unit 91. The first system unit 10 includes, for example, a CPU (Central Processing Unit) (not illustrated) that executes predetermined arithmetic processing and an EEPROM (Electrically Erasable and Programmable Read Only Memory) that stores a predetermined control program. A nonvolatile memory, a RAM (Dynamic Random Access Memory) (not shown) for temporarily storing data, and peripheral circuits thereof are provided. The first system unit 10 includes a first load unit 14. The first system unit 10 configures a detection unit 12, a reset control unit 13, and a first control unit 15 by causing a CPU to execute a control program stored in a nonvolatile memory.

  The first load unit 14 is a plurality of loads that operate using the first power supply voltage V <b> 1 supplied from the first power supply unit 91 under the control of the first control unit 15. Specifically, the load included in the first load unit 14 includes the image forming unit 80 and the display unit 51.

  The first load unit 14 includes a plurality of capacitive loads 14-1 to 14 -m included in a control circuit that controls operations of the plurality of loads included in the first load unit 14. Specifically, the plurality of capacitive loads 14-1 to 14-m include, for example, a rotation operation of the photosensitive drum 81, a charging operation by the charger 82, an operation of irradiating an optical signal by the exposure device 83, and a developing device. 84 included in the control circuit for controlling the operation of applying the developing bias voltage to 84, the operation of the image forming unit 80 such as the rotating operation of the transfer roller 85, and the operation of displaying information on the display unit 51. A capacitive load capable of storing predetermined power is included.

  The detection unit 12 monitors the commercial AC voltage input to the first power supply unit 91 and detects supply and interruption of the commercial AC voltage based on the zero cross point of the commercial AC voltage. Specifically, the detection unit 12 detects a commercial AC voltage interruption when it cannot detect the zero cross point of the commercial AC voltage within a half of a predetermined period of the commercial AC voltage. Is output to the first reset control unit 13. On the other hand, while the detection unit 12 can detect the zero-cross point of the commercial AC voltage within a half of the predetermined period of the commercial AC voltage, the detection unit 12 outputs a detection signal indicating the supply of the commercial AC voltage to the first reset control unit. 13 to output.

  The reset control unit 13 outputs a reset signal R1 indicating an instruction to reset the first load unit 14 to the first control unit 15 based on the detection signal indicating the interruption of the commercial AC voltage input from the detection unit 12, Further, a reset signal R <b> 2 indicating an instruction to reset a second load unit 24 described later is output to the second control unit 25 described later. Details of the reset signal R1 and the reset signal R2 will be described later. Details of the operation of the reset control unit 13 outputting the reset signal R1 and the reset signal R2 will be described later.

  The first control unit 15 performs overall control of a control circuit that controls the operation of each load included in the first load unit 14. For example, the first control unit 15 controls the control circuit that controls the operation of the image forming unit 80 and the control circuit that controls the operation of the display unit 51, displays various information on the display unit 51, and then performs image formation. The unit 80 is caused to execute an image forming operation.

  Moreover, the 1st control part 15 will reset the 1st load part 14, if the reset signal R1 is input from the 1st reset control part 13. FIG. Here, resetting the first load unit 14 returns the state of the control circuit that controls the operation of each load included in the first load unit 14 to the initial initial state in which the first power supply voltage V1 is supplied. Indicates. For example, when resetting the first load unit 14, the first control unit 15 reads a control program for causing the image forming unit 80 to perform an image forming operation from the nonvolatile memory, and controls the operation of the image forming unit 80. And stored in a RAM provided in the control circuit.

  The second system unit 20 operates in response to the supply of the second power supply voltage V2 generated by the second power supply unit 92. The second system unit 20 includes, for example, a CPU (Central Processing Unit) (not illustrated) that executes predetermined arithmetic processing and an EEPROM (Electrically Erasable and Programmable Read Only Memory) that stores a predetermined control program. A nonvolatile memory, a RAM (Dynamic Random Access Memory) (not shown) for temporarily storing data, and peripheral circuits thereof are provided. The second system unit 20 includes a second load unit 24. The second system unit 20 configures the second control unit 25 by causing the CPU to execute a control program stored in the nonvolatile memory.

  The second load unit 24 is a plurality of loads that operate using the second power supply voltage V <b> 2 supplied from the second power supply unit 92 under the control of the second control unit 25. Specifically, the load included in the second load unit 24 includes an operation key unit 52 and a network interface circuit (not shown).

  The second load unit 24 includes a plurality of capacitive loads 24-1 to 24-n included in a control circuit that controls operations of the plurality of loads included in the second load unit 24. Specifically, the plurality of capacitive loads 24-1 to 24-n receive image data by, for example, receiving an operation instruction of the operation key unit 52 performed by the user or a network interface circuit (not shown). A capacitive load that can store predetermined power, such as a capacitor, included in a control circuit that controls the operation is included. Note that the load of the operation key unit 52 and the like included in the second load unit 24 can be operated with a small amount of electric power compared to the load of the image forming unit 80 and the like included in the first load unit 14. The power that can be stored in 24-1 to 24-n is configured to be smaller than the power that can be stored in the capacitive loads 14-1 to 14-m included in the first load unit 14.

  The second control unit 25 performs overall control of a control circuit that controls the operation of each load included in the second load unit 24. For example, the second control unit 25 controls the control circuit that controls the operation of the operation key unit 52 and the control circuit that controls the operation of the network interface circuit (not shown), and the image data performed by the user is transferred to an external computer. After receiving the operation instruction of the operation key unit 52 for transmitting to the network, the network interface circuit transmits the image data to an external computer.

  Moreover, the 2nd control part 25 will reset the 2nd load part 24, if the reset signal R2 is input from the 1st reset control part 13. FIG. Here, resetting the second load unit 24 returns the state of the control circuit that controls the operation of each load included in the second load unit 24 to the initial state in which the second power supply voltage V2 is supplied. Indicates. For example, when resetting the second load unit 24, the second control unit 25 reads a control program for causing the network interface circuit to receive image data from the nonvolatile memory, and controls the operation of the network interface circuit. And stored in a RAM provided in the control circuit.

  FIG. 3 is a timing chart illustrating an operation in which the reset control unit 13 resets the first load unit 24 and the second load unit 24.

  As shown in FIG. 3, the detector 12 detects the commercial AC voltage within a period (Tac / 2) that is a half of a predetermined cycle Tac of the commercial AC voltage supplied from the commercial AC power supply AC (FIG. 2). When the zero cross point is no longer detected, a detection signal indicating the interruption of the commercial AC voltage is output to the reset control unit 13.

  When the detection signal indicating the interruption of the commercial AC voltage is output by the detection unit 12, the first power supply voltage V 1 is not generated in the first power supply unit 91 and the second power supply voltage is generated in the second power supply unit 92. V2 is no longer generated. Accordingly, the first load unit 14 operates using the electric power stored in the capacitive loads 14-1 to 14-m, and the second load unit 24 is operated using the capacitive loads 24-1 to 24- It operates using the electric power stored in n.

  The reset control unit 13 sets the reset signal R1 and the reset signal R2 to high (Hi) for a predetermined first time limit T1 from the time Ts when the detection signal indicating the interruption of the commercial AC voltage is input from the detection unit 12. ) Wait in level.

  The first control unit 15 does not reset the first load unit 14 while the reset signal R1 is at the high level, continues the operation of the first load unit 14, and the reset signal R1 switches to the low (Lo) level. The first load unit 14 is reset, and the first load unit 14 is maintained in a reset state while the reset signal R1 is at a low level. Similarly, the second control unit 25 does not reset the second load unit 24 while the reset signal R2 is at the high level, continues the operation of the second load unit 24, and the reset signal R2 goes to the low (Lo) level. When switched, the second load unit 24 is reset, and the second load unit 14 is maintained in a reset state while the reset signal R2 is at a low level.

  Here, the first time limit T1 is determined in advance based on experimental values such as test operation. Specifically, the second load unit 24 uses the electric power stored in the capacitive loads 24-1 to 24-n from the time Ts when the detection signal indicating the interruption of the commercial AC voltage is input from the detection unit 12. It works for a while. However, when the voltage supplied by the power stored in the capacitive loads 24-1 to 24-n reaches the voltage Vd2 necessary for the operation of the second load unit 24, the second load unit 24 cannot operate. As described above, from the time Ts when the detection signal indicating the interruption of the commercial AC voltage is input from the detection unit 12, the second load unit 24 is operated using the electric power stored in the capacitive loads 24-1 to 24-n. The period until it cannot be made is predetermined as the first time limit T1.

  When the first limit time T1 has elapsed from the time Ts when the detection signal indicating the interruption of the commercial AC voltage is input from the detection unit 12, the reset control unit 13 receives the detection signal indicating the interruption of the commercial AC voltage from the detection unit 12. When the signal remains input, a low-level reset signal R2 is output to the second control unit 25. As a result, the second control unit 25 resets the second load unit 24.

  In particular, in this embodiment, since instantaneous interruption of the commercial AC voltage is assumed, the period from the time Ts when the detection signal indicating the interruption of the commercial AC voltage is input from the detection unit 12 until the first time limit T1 elapses. In addition, a detection signal indicating supply of commercial AC voltage may be input from the detection unit 12. However, in this case, since the second load unit 24 can operate using the electric power stored in the capacitive loads 24-1 to 24-n, there is no need to reset the second load unit 24. Therefore, in the present embodiment, the reset control unit 13 receives the detection signal indicating the interruption of the commercial AC voltage from the detection unit 12 while the detection signal indicating the interruption of the commercial AC voltage is input from the detection unit 12. The second load unit 24 is reset after waiting for the first time limit T1 to elapse from the time Ts.

  Thereafter, the detection unit 12 detects the zero cross point of the commercial AC voltage within a period (Tac / 2) of a predetermined period Tac of the commercial AC voltage supplied from the commercial AC power supply AC (FIG. 2). Then, a detection signal indicating supply of the commercial AC voltage is output to the reset control unit 13.

  When the detection unit 12 outputs the detection signal indicating the supply of the commercial AC voltage, the supply of the first power supply voltage V1 from the first power supply unit 91 to the first system unit 10 is resumed. The supply of the second power supply voltage V2 from the power supply unit 92 to the second system unit 20 is resumed. As a result, the voltage used for the operation of the first load unit 14 and the voltage used for the operation of the second load unit 24 rise again.

  When a predetermined second time limit T2 has elapsed from the time Ts when the detection signal indicating the interruption of the commercial AC voltage is input from the detection unit 12, the reset control unit 13 outputs the low-level reset signal R1 to the first control unit. 15 is output. As a result, the first control unit 15 resets the first load unit 14.

  Here, the second time limit T2 is determined in advance based on experimental values such as test operation. Specifically, the first load unit 14 uses the electric power stored in the capacitive loads 14-1 to 14-m from the time Ts when the detection signal indicating the interruption of the commercial AC voltage is input from the detection unit 12. In other words, the operation is performed for a time longer than the first time limit T1 using electric power larger than the electric power stored in the capacitive loads 24-1 to 24-n of the second load unit 24. However, when the voltage supplied by the electric power stored in the capacitive loads 14-1 to 14-m reaches the voltage Vd1 necessary for the operation of the first load unit 14, the first load unit 14 cannot operate. As described above, the first load unit 14 is operated using the electric power stored in the capacitive loads 14-1 to 14-m from the time Ts when the detection signal indicating the interruption of the commercial AC voltage is input from the detection unit 12. The period until it cannot be made is predetermined as the second time limit T2.

  In addition, the reset control unit 13 is configured to restart the operation of the second load unit 24 when the second time limit T2 has elapsed from the time Ts when the detection signal indicating the interruption of the commercial AC voltage is input from the detection unit 12. The level reset signal R2 is output to the second control unit 25. As a result, the second control unit 25 resumes the operation of the second load unit 24.

  Further, the reset control unit 13 is required to reset the first load unit 14 from the time when the second time limit T2 has elapsed from the time Ts when the detection signal indicating the interruption of the commercial AC voltage is input from the detection unit 12. When a predetermined period T3 elapses as a time, a high level reset signal R1 is sent to the first control unit 15. Accordingly, the first control unit 15 restarts the operation of the first load unit 14.

  According to the structure of the said embodiment, when the interruption | blocking of commercial alternating voltage is detected by the detection part 12, 1st time limit T1 passes from the detection time of the said interruption | blocking, ie, the 2nd load part 24 is capacitive. When it is considered that the operation cannot be performed with the electric power stored in the loads 24-1 to 24-n, and the interruption of the commercial AC voltage is still detected by the detection unit 12, the second load unit 24 is reset. Thereafter, the first load unit 14 is reset. For this reason, when interruption | blocking of commercial alternating voltage is detected by the detection part 12, since the 1st load part 14 and the 2nd load part 24 have been reset, after that, supply of commercial alternating voltage When the operation is restarted, it is possible to reduce a possibility that an operation mismatch occurs between the first load unit 14 and the second load unit 24.

  In addition, after the second load unit 24 is reset and before the second limit time T2 elapses from the commercial AC voltage supply interruption detection time Ts, that is, the first load unit 14 has the capacitive loads 14-1 to 14-14. When the first load unit 14 is reset while the supply of the commercial AC voltage is not detected by the detection unit 12 when it is considered that the operation is performed with the electric power stored in −m, the operation of resetting the first load unit 14 is performed. Therefore, there is a possibility that the first load unit 14 cannot be normally reset.

  However, according to the configuration of the above embodiment, after the second load unit 24 is reset, until the second time limit T2 elapses from the commercial AC voltage supply cutoff detection time Ts, that is, the first load unit. 14 is considered to be operating with the electric power stored in the capacitive loads 14-1 to 14-m, and when the supply of the commercial AC voltage is detected, the first after the supply of the commercial AC voltage is detected. 1 load part 14 is reset. Therefore, the first load unit 14 can be reliably reset in a state where the first power supply voltage V1 is supplied from the first power supply unit 91 to the first load unit 14 by supplying the commercial AC voltage. As a result, when the supply of the commercial AC voltage is resumed, the first load unit 14 and the second load unit 24 are both reset and operated between the first load unit 14 and the second load unit 24. It is possible to reduce the possibility of inconsistency.

  Further, when the supply of the commercial AC voltage is detected after the second load unit 24 is reset and the second limit time T2 elapses from the time Ts when the interruption of the commercial AC voltage is detected, that is, the first When it is considered that the load unit 14 is operating with the electric power stored in the capacitive loads 14-1 to 14-m, when the supply of the commercial AC voltage is detected, the interruption of the commercial AC voltage is detected. When the second time limit T2 has elapsed from the time Ts, the first power supply voltage V1 is supplied from the first power supply unit 91 to the first load unit 14.

  In other words, according to the configuration of the above embodiment, the first load unit 14 is reset when the second time limit T2 has elapsed from the time Ts when the interruption of the commercial AC voltage is detected. The first load unit 14 can be reliably reset while the first power supply voltage V1 is supplied to the first load unit 14. As a result, when the supply of the commercial AC voltage is resumed, the first load unit 14 and the second load unit 24 are both reset and operated between the first load unit 14 and the second load unit 24. It is possible to reduce the possibility of inconsistency.

  In addition, when the supply of the commercial AC voltage is resumed after the supply of the commercial AC voltage is interrupted, the first load unit 14 and the second load unit 24 are both reset, so the first It is possible to reduce the possibility of inconsistency in operation between the image forming unit 80 and the second load unit 24 included in the load unit 14.

  In the above embodiment, the configuration shown in FIGS. 1 to 3 is merely an example, and the present invention is not limited to the embodiment.

  For example, in the above embodiment, the reset control unit 13 causes the detection unit 12 to execute the commercial AC when the first time limit T1 has elapsed from the time Ts when the detection signal indicating the interruption of the commercial AC voltage is input from the detection unit 12. When the interruption of the voltage remains detected, the second load unit 24 is reset, and then the first load unit 14 is reset when the second time limit T2 elapses from the time Ts when the detection signal is input. Was.

  However, instead of this, the reset control unit 13 causes the detection unit 12 to execute the commercial AC when the first time limit T1 has elapsed from the time Ts when the detection signal indicating the interruption of the commercial AC voltage is input from the detection unit 12. When the interruption of the voltage remains detected, the second load unit 24 is reset, and at the time Tr (FIG. 3) when the detection signal indicating the supply of the commercial AC voltage is input from the detection unit 12, the low level is detected. The reset signal R1 may be output to the first control unit 15 to reset the first load unit 14. In accordance with this, the reset control unit 13 restarts the operation of the second load unit 24 at the time Tr (FIG. 3) when the detection signal indicating the supply of the commercial AC voltage is input from the detection unit 12. A high-level reset signal R2 may be output to the second control unit 25.

  In this case, since the first load unit 14 is reset when the supply of the commercial AC voltage is detected after the second load unit 24 is reset, from the time Ts when the interruption of the commercial AC voltage is detected, The first load unit 14 can be quickly reset without waiting until the time when the first load unit 14 is considered to be unable to operate with the power stored in the capacitive loads 14-1 to 14-m. As a result, when the supply of the commercial AC voltage is resumed, the first load unit 14 and the second load unit 24 are both reset and operated between the first load unit 14 and the second load unit 24. It is possible to reduce the possibility of inconsistency.

  Alternatively, the reset control unit 13 does not output the low-level reset signal R1 to the first control unit 15 at the time Tr (FIG. 3) when the detection signal indicating supply of the commercial AC voltage is input from the detection unit 12. The low-level reset signal R1 is sent to the first control unit 15 at any timing within the period from the time point Tr to the time point when the second time limit T2 has elapsed from the time point Ts at which the interruption of the commercial AC voltage is detected. In order to reset the first load unit 14 and resume the operation of the second load unit 24, a high level reset signal R2 may be output to the second control unit 25.

  Note that when the interruption of the commercial AC voltage continues to be detected even after the second time limit T2 has elapsed from the time Ts when the interruption of the commercial AC voltage is detected, the first load unit 14 and the second load unit 24 are Since both of them do not operate, when the supply of the commercial AC voltage is resumed, the first load unit 14 and the second load unit 24 are both reset. As a result, the possibility of inconsistencies in the operations of the first load unit 14 and the second load unit 24 is reduced.

  Moreover, in the said embodiment, the detection part 12 detected supply and interruption | blocking of the commercial alternating voltage based on the zero crossing point of the commercial alternating voltage. However, the present invention is not limited to this, and the detection unit 12 monitors the voltage level of the commercial AC voltage, for example, and when the voltage level does not fluctuate within a predetermined period, the detection signal indicating the interruption of the commercial AC voltage. And a detection signal indicating supply of the commercial AC voltage may be output while the voltage level fluctuates more than a predetermined level within a predetermined period.

  The voltage supplied to the first power supply unit 91 and the second power supply unit 92 may be a DC voltage supplied from a power supply device outside the printer 1. Accordingly, the first power supply unit 91 may be configured to include a DC / DC converter that converts the supplied DC voltage into the first power supply voltage V1. Similarly, the second power supply unit 92 may be configured to include a DC / DC converter that converts the supplied DC voltage into the second power supply voltage V2.

1 Printer (image forming device)
DESCRIPTION OF SYMBOLS 10 1st system part 12 Detection part 13 Reset control part 14 1st load part 14-1 to 14-m Capacitive load of 1st load part 15 1st control part 20 2nd system part 24 2nd load part 24-1 -24-n Capacitive load of second load unit 25 Second control unit 50 Operation unit 51 Display unit 52 Operation key unit 80 Image forming unit 90 Power supply device 91 First power supply unit 92 Second power supply unit AC Commercial AC power supply R1 Reset Signal R2 Reset signal T1 1st time limit T2 2nd time limit V1 1st power supply voltage V2 2nd power supply voltage

Claims (6)

A first power supply unit that generates a predetermined first power supply voltage using an external voltage;
A second power supply unit that generates a second power supply voltage smaller than the first power supply voltage using the external voltage;
A detector for detecting supply and interruption of the external voltage;
A first load unit having a capacitive load capable of storing predetermined power and operating using the first power supply voltage;
A second load unit having a capacitive load capable of storing electric power smaller than electric power that can be stored in the first load unit, and operating using the second power supply voltage;
When the first power supply voltage is operated and the external voltage is detected by the detection unit, the power stored in the capacitive load of the second load unit is detected from the detection point of the interruption. When the first limit time that is predetermined as a time during which the two load units can be operated has elapsed, and the detection of the external voltage is still detected by the detection unit, the second load unit is A reset control unit for resetting the first load unit after resetting;
A power supply device comprising:   The reset control unit can operate the first load unit with the electric power stored in the capacitive load of the first load unit after the detection of the interruption after resetting the second load unit. 2. The power supply device according to claim 1, wherein when the supply is detected by the detection unit before a second time limit predetermined as a time elapses, the first load unit is reset after the supply is detected. .   The reset control unit can operate the first load unit with the electric power stored in the capacitive load of the first load unit after the detection of the interruption after resetting the second load unit. When the supply is detected by the detection unit before the second time limit predetermined as the time elapses, the first load unit when the second time limit elapses from the detection time of the shutoff. The power supply device according to claim 2, wherein the power supply device is reset.   The power supply apparatus according to claim 2, wherein the reset control unit resets the first load unit when the supply is detected by the detection unit after resetting the second load unit. The external voltage is an alternating voltage,
5. The power supply device according to claim 1, wherein the detection unit detects supply and interruption of the external voltage based on a zero-cross point of the AC voltage. A power supply device according to any one of claims 1 to 5, comprising:
The image forming apparatus includes an image forming unit that forms an image on a sheet in the first load unit.

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