JP2017062417A - Image forming apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image forming apparatus that can monitor a power to be supplied while reducing cost.SOLUTION: A compound machine 11 comprises a monitoring circuit 41. The monitoring circuit 41 includes an overvoltage detection circuit 42, a power supply voltage detection circuit 43, a zero-cross detection circuit 44, and a microcomputer 45. The overvoltage detection circuit 42 includes a first full wave rectifier diode 51a, a constant voltage diode 52, a first resistor 53a, and a second resistor 53b. The power supply voltage detection circuit 43 includes a second full wave rectifier diode 51b, a capacitor 54, and a third resistor 53c. The zero-cross detection circuit 44 includes a third full wave rectifier diode 51c, a transistor 55, a fourth resistor 53d, and a fifth resistor 53e. The microcomputer 45 receives the AC outputs from the overvoltage detection circuit 42, the power supply voltage detection circuit 43, and the zero-cross detection circuit 44.SELECTED DRAWING: Figure 4

Description

  The present invention relates to an image forming apparatus.

  In an image forming apparatus typified by a multifunction peripheral or the like, after an image of a document is read by an image reading unit, light is irradiated on the photoconductor provided in the image forming unit based on the read image, An electrostatic latent image is formed on the surface. Thereafter, a developer is supplied onto the formed electrostatic latent image to form a visible image, which is then transferred and fixed on paper, and discharged out of the apparatus.

  The image forming apparatus is externally supplied with power required for driving the image forming unit and transporting the paper. In the electric power supplied from the outside, an instantaneous power failure, that is, an instantaneous power failure or intermittent generation of leakage current may occur. Japanese Laid-Open Patent Publication No. 2006-238511 (Patent Document 1) discloses a power supply monitoring recorder that monitors the occurrence of such an instantaneous power failure or leakage current.

JP 2006-238511 A

  As for the power supplied to the image forming apparatus, depending on the quality of the power, an instantaneous power failure may occur or an overvoltage or surge voltage may be applied. Such an instantaneous power failure may cause a malfunction of the image forming apparatus, but there are many cases where the failure occurs due to a temporary power failure. Have difficulty. Therefore, it is necessary to grasp the occurrence of a momentary power interruption or the like.

  According to Patent Document 1, the power supply monitoring recorder monitors the load current and the line voltage to detect the occurrence of instantaneous power failure or leakage current. However, in such a configuration, the load current and the line voltage must be monitored at the same time, and it is necessary to provide a current sensor for monitoring the current. Such a current sensor is relatively expensive and it is difficult to realize low cost.

  An object of the present invention is to provide an image forming apparatus capable of monitoring the power supplied while reducing the cost.

  In one aspect of the present invention, an image forming apparatus includes an image forming unit that forms an image. The image forming apparatus includes a monitoring circuit. The monitoring circuit monitors the input state of the power supplied to the image forming apparatus. The monitoring circuit includes an overvoltage detection circuit, a power supply voltage detection circuit, a zero cross detection circuit, and a microcomputer. The overvoltage detection circuit includes a first full-wave rectifier diode, a constant voltage diode, a first resistor, and a second resistor. The overvoltage detection circuit detects an overvoltage generated in the monitoring circuit. The power supply voltage detection circuit includes a first full-wave rectifier diode and a second full-wave rectifier diode provided separately, a capacitor, and a third resistor provided separately from the first and second resistors. The power supply voltage detection circuit detects an AC input supplied from a power supply. The zero cross detection circuit includes a first full-wave rectifier diode and a third full-wave rectifier diode separately provided, a transistor, and a fourth resistor provided separately from the first to third resistors, And a fifth resistor. The zero cross detection circuit detects passage of a zero point when the AC input is turned on or off. The microcomputer receives AC outputs from an overvoltage detection circuit, a power supply voltage detection circuit, and a zero cross detection circuit.

  According to such a configuration, an overvoltage detection circuit, a power supply voltage detection circuit, and a detection result by a zero cross detection circuit included in the monitoring circuit are input to a microcomputer to monitor an overvoltage generated in the supplied power supply. Can do. In this case, since it is not necessary to monitor the current value itself, it is not necessary to provide a current sensor, and overvoltage, power supply voltage, and zero crossing can be monitored. Therefore, the image forming apparatus having such a configuration can monitor the supplied power while reducing the cost.

1 is a diagram illustrating an external appearance of a multifunction peripheral when an image forming apparatus according to an embodiment of the present invention is applied to the multifunction peripheral. FIG. 2 is a block diagram illustrating a configuration of the multifunction machine illustrated in FIG. 1. It is an external view which shows the structure of an operation part. It is a figure which shows the structure of a monitoring circuit.

  Embodiments of the present invention will be described below. FIG. 1 is a diagram illustrating an appearance of a multifunction peripheral when an image forming apparatus according to an embodiment of the present invention is applied to the multifunction peripheral. FIG. 2 is a block diagram illustrating a configuration of the multifunction peripheral illustrated in FIG.

  With reference to FIGS. 1 to 2, a multifunction machine 11 as an image forming apparatus according to an embodiment of the present invention includes a control unit 12, an operation unit 13, an image reading unit 14, an image forming unit 15, A hard disk 16 for storing data, a facsimile communication unit 17, a manual feed tray 28, three paper feed cassettes 23 a to 23 c, a network interface unit 18 for connection to the network 25, and a monitoring circuit 41 are provided.

  The control unit 12 controls the entire multifunction machine 11. The operation unit 13 includes a display screen 21 that displays information transmitted from the multifunction peripheral 11 side and user input contents. The operation unit 13 inputs image forming conditions such as the number of copies to be printed and gradation, and power on / off. The image reading unit 14 includes an automatic document feeder (ADF (Auto Document Feeder)) 22 that automatically conveys a set document to a reading position. The image reading unit 14 reads an image of a document conveyed by the ADF 22 and an image of a document placed on a placement table (not shown). The manual feed tray 28 sets paper as a recording medium manually. Each of the paper feed cassettes 23a to 23c accommodates therein a paper on which an image is to be formed. The image forming unit 15 includes a developing device 29 that forms a visible image with toner. The image forming unit 15 forms an image based on the read image and image data transmitted via the network 25. That is, the image forming unit 15 sets an image on a recording medium, for example, a sheet that is set in the paper feed cassette 23a and conveyed toward the image forming unit 15 based on the image data in response to the received image formation request. Form. The sheet on which the image is formed by the image forming unit 15 is discharged to the discharge tray 30. The hard disk 16 stores transmitted image data, input image forming conditions, and the like. The facsimile communication unit 17 is connected to the public line 24 and performs facsimile transmission and facsimile reception. The monitoring circuit 41 monitors the input state of the power supply 19 supplied to the multifunction machine 11.

  The multi-function device 11 includes a DRAM (Dynamic Random Access Memory) for writing and reading image data, and the illustration and description thereof are omitted. In addition, arrows in FIG. 2 indicate the flow of data regarding control signals, control, and images.

  The multifunction machine 11 operates as a copying machine by forming an image in the image forming unit 15 using the image data of the original read by the image reading unit 14 and printing it on a sheet. Further, the multifunction machine 11 forms an image in the image forming unit 15 using the image data transmitted from the computers 26a, 26b, and 26c connected to the network 25 through the network interface unit 18, and prints it on a sheet. It operates as a printer. That is, the image forming unit 15 operates as a printing unit that prints the requested image. In addition, the multifunction machine 11 forms an image in the image forming unit 15 via the DRAM using the image data transmitted from the public line 24 through the facsimile communication unit 17, and the image reading unit 14 reads the image. By transmitting the image data of the original document to the public line 24 through the facsimile communication unit 17, the facsimile apparatus operates. That is, the multifunction machine 11 has a plurality of functions such as a copying function, a printer function, and a facsimile function with respect to image processing. Further, each function has functions that can be set in detail.

  The image forming system 27 including the multifunction device 11 includes the multifunction device 11 and a plurality of computers 26a, 26b, and 26c. Specifically, the image forming system 27 includes the multifunction device 11 having the above-described configuration and a plurality of computers 26 a, 26 b, and 26 c connected to the multifunction device 11 via the network 25. In this embodiment, three computers 26a to 26c are shown.

  Next, the configuration of the operation unit 13 described above will be described in more detail. FIG. 3 is an external view showing a schematic configuration of the operation unit 13. Referring to FIG. 3, the operation unit 13 includes a numeric keypad 31 for inputting numbers from 0 to 9 for inputting the number of copies to be printed, and symbols of “*” and “#”, and start of printing and facsimile transmission. A start key 32 for instructing the start of the printer, a power key 33 for inputting power on / off of the multifunction device 11, a menu key 34 for instructing selection of a printer function, a copy function, etc. of the multifunction device 11, A registration key 35 for instructing image forming conditions and user registration, a reset key 36 for canceling the contents of an instruction input by the user using the numeric keypad 31 and the like, and the display screen 21 described above are included. The display screen 21 has a liquid crystal touch panel function, and allows the user to input image forming conditions and the like from the display screen 21 and select a function by pressing with a user's finger.

  Next, the configuration of the monitoring circuit 41 will be described in more detail. FIG. 4 is a diagram illustrating a configuration of the monitoring circuit 41. 1 to 4, the monitoring circuit 41 includes an overvoltage detection circuit 42, a power supply voltage detection circuit 43, a zero-cross detection circuit 44, and a microcomputer (hereinafter sometimes abbreviated as “microcomputer”) 45. With. That is, the monitoring circuit 41 has a configuration in which an overvoltage detection circuit 42, a power supply voltage detection circuit 43, a zero cross detection circuit 44, and a microcomputer 45 are incorporated. The overvoltage detection circuit 42 is indicated by a broken line. The power supply voltage detection circuit 43 is indicated by a one-dot chain line. The zero cross detection circuit 44 is indicated by a two-dot chain line. The microcomputer 45 includes a memory 46 as a storage unit that stores input data in a storage area and a timer 47 that measures time. The microcomputer 45 receives AC (Alternating Current) output from the overvoltage detection circuit 42, the power supply voltage detection circuit 43, and the zero cross detection circuit 44. A motor (not shown) for driving the image forming unit 15 is provided on the load 20 side in the monitoring circuit 41.

  Monitoring circuit 41 further includes an ACDC (Alternating Current Direct Current) converter 48 and a full-wave rectifier diode 49. The ACDC converter 48 converts alternating current and direct current. The microcomputer 45 is driven by a battery (not shown) provided outside the power supply 19 so that the power input generated by the ACDC converter 48 and the AC input can be monitored and stored even if the AC input fails. Is done.

  The overvoltage detection circuit 42 includes a first full-wave rectifier diode 51a, a constant voltage diode 52, a first resistor 53a, and a second resistor 53b. The overvoltage detection circuit 42 performs full-wave rectification on the AC input by a full-wave rectifier diode 51a as a bridge diode, divides the voltage by the constant voltage diode 52 and the resistors 53a and 53b, and inputs them to the microcomputer 45 for monitoring. Detects overvoltage. In this case, the overvoltage detection circuit 42 does not detect a voltage lower than a certain voltage, for example, 100V, and detects a portion exceeding 150V.

  The power supply voltage detection circuit 43 detects whether or not the voltage from the power supply 19 is appropriate. The power supply voltage detection circuit 43 is provided separately from the first full-wave rectifier diode 51a and the second full-wave rectifier diode 51b provided separately, the capacitor 54, and the first and second resistors 53a and 53b. And a third resistor 53c. The power supply voltage detection circuit 43 performs full-wave rectification on the AC input by a full-wave rectifier diode 51b as a bridge diode, smoothes it with a capacitor 54, inputs it to the microcomputer 45, and monitors it, so that the voltage from the power supply 19 is appropriate. Detect whether or not there is. A resistor 53c is provided to step down the voltage to a voltage that can be input to the microcomputer 45.

  The zero cross detection circuit 44 detects passage of a zero point when the AC input is turned on or off. The zero-cross detection circuit 44 includes first and second full-wave rectifier diodes 51a and 51b, a third full-wave rectifier diode 51c provided separately, a transistor 55, and first to third resistors 53a to 53c. A fourth resistor 53d and a fifth resistor 53e provided separately are included. The zero cross detection circuit 44 detects the zero cross by detecting the AC input zero cross with the resistors 53d and 53e, and inputting to the microcomputer 45 for monitoring. Specifically, when the number of zero crosses per second is input at an interval of 8.3 msec for AC 50 Hz and 10 msec for AC 50 Hz as a normal value, the timer 47 measures the time when the zero cross is not input, Detects instantaneous power failure time with AC input.

  According to the multi-function device 11 having such a configuration, the power supplied by inputting the detection results of the overvoltage detection circuit 42, the power supply voltage detection circuit 43, and the zero cross detection circuit 44 included in the monitoring circuit 41 to the microcomputer 45. The overvoltage or the like generated at 19 can be monitored. In this case, since it is not necessary to monitor the current value itself, it is not necessary to provide a current sensor, and overvoltage, power supply voltage, and zero crossing can be monitored. Therefore, the MFP 11 having such a configuration can monitor the supplied power source 19 while reducing the cost.

  Specifically, in this case, it is possible to detect an AC input surge voltage, an AC input power supply voltage, an AC input power failure, and a power failure time. Then, from this detection result, it is possible to grasp the abnormal operation of the multifunction device 11 related to the AC input. Further, from the data stored in the memory 46, it is possible to track how many times the AC input overvoltage has occurred during the life of the multi-function device 11, that is, during the lifetime operation. Further, it is possible to specify a part to be replaced when the multifunction machine 11 is recycled from the detection result and the grasp.

  In this case, the microcomputer 45 includes a memory 46 for storing AC output data from the overvoltage detection circuit 42, the power supply voltage detection circuit 43, and the zero-cross detection circuit 44. More accurate monitoring can be performed in association with data.

  In the above embodiment, the microcomputer 45 includes the memory 46 for storing the output results from the overvoltage detection circuit 42, the power supply voltage detection circuit 43, and the zero cross detection circuit 44. However, the present invention is not limited to this. An external memory may be provided outside the microcomputer 45, and the microcomputer 45 may be configured to store the output results from the overvoltage detection circuit 42, the power supply voltage detection circuit 43, and the zero cross detection circuit 44.

  In the above embodiment, the detection result input to the microcomputer 45 may be displayed on the display screen 21 of the operation unit 13 as a graph or the like for monitoring. That is, the display screen 21 that displays the input result input to the microcomputer 45 may be provided. By doing so, the multifunction machine 11 can visually indicate the detection result and make it easier to grasp the detection result.

  It should be understood that the embodiments and examples disclosed herein are illustrative in all respects and are not restrictive in any respect. The scope of the present invention is defined by the scope of the claims, rather than the description above, and is intended to include any modifications within the scope and meaning equivalent to the scope of the claims.

  The image forming apparatus according to the present invention is particularly effectively used when cost reduction and monitoring of supplied power are required.

  DESCRIPTION OF SYMBOLS 11 MFP, 12 Control part, 13 Operation part, 14 Image reading part, 15 Image formation part, 16 Hard disk, 17 Facsimile communication part, 18 Network interface part, 19 Power supply, 20 Load, 21 Display screen, 22 ADF, 23a, 23b, 23c Paper cassette, 24 Public line, 25 Network, 26a, 26b, 26c Computer, 27 Image forming system, 28 Manual feed tray, 29 Developing device, 30 Eject tray, 31 Numeric keypad, 32 Start key, 33 Power key, 34 Menu key, 35 Registration key, 36 Reset key, 41 Monitoring circuit, 42 Overvoltage detection circuit, 43 Power supply voltage detection circuit, 44 Zero cross detection circuit, 45 Microcomputer, 46 Memory, 47 Timer, 48 ACDC Barter, 49,51a, 51b, 51c full wave rectifier diode, 52 a constant voltage diode, 53a, 53b, 53c, 53d, 53e resistor, 54 a capacitor, 55 a transistor.

Claims (5)

An image forming apparatus including an image forming unit for forming an image,
A monitoring circuit for monitoring an input state of a power source supplied to the image forming apparatus;
The monitoring circuit is
An overvoltage detection circuit including a first full-wave rectifier diode, a constant voltage diode, a first resistor and a second resistor, and detecting an overvoltage generated in the monitoring circuit;
A second full-wave rectifier diode provided separately from the first full-wave rectifier diode, a capacitor, and a third resistor provided separately from the first and second resistors; A power supply voltage detection circuit for detecting an AC input to be transmitted;
A third full-wave rectifier diode provided separately from the first and second full-wave rectifier diodes, a transistor, and a fourth resistor provided separately from the first to third resistors, and A zero cross detection circuit that includes a fifth resistor and detects the passage of a zero point when the AC input is on or off;
An image forming apparatus comprising: the overvoltage detection circuit; the power supply voltage detection circuit; and a microcomputer to which an AC output from the zero cross detection circuit is input. The image forming apparatus according to claim 1, further comprising a storage unit that stores data of AC output from the overvoltage detection circuit, the power supply voltage detection circuit, and the zero cross detection circuit. The image forming apparatus according to claim 2, wherein the microcomputer includes the storage unit. The image forming apparatus according to claim 1, further comprising a display screen that displays an input result input to the microcomputer. The image forming apparatus according to claim 1, wherein the microcomputer is driven by a battery provided outside the power source.