JP2013182006A - Image forming apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To further reduce power consumption of an image forming apparatus with option devices attached thereto.SOLUTION: In an image forming apparatus comprising an apparatus body for forming an image on printing paper and one or more option devices attached to the apparatus body, a body control section and an option control section are connected via serial communication lines, and among at least the serial communication lines, a communication preparation signal line used to inform the body control section that the option control section is in a state of being able to communicate is connected to an interruption terminal of the body control section. When informing the body control section, in the power saving mode of the body control section, of a change in the status of the option device, the option control section varies the potential of the communication preparation signal line. When detecting the potential change of the communication preparation signal line as interruption input in the power saving mode, the body control section resumes to a normal operation mode from the power saving mode.

Description

 The present invention relates to an image forming apparatus.

 In the following Patent Document 1, in an image forming apparatus equipped with an optional device, after the CPU of the apparatus main body is switched to the power saving mode, the CPU of the optional apparatus notifies the CPU of the apparatus main body of a change in the state of the own apparatus. In this case, the logic of the data signal line used for serial communication with the CPU of the apparatus main body is inverted for a certain time, and the CPU of the apparatus main body returns to the normal mode when detecting the logic inversion of the data signal line in the power saving mode, A technique for starting communication with an optional device is disclosed.

JP 2009-148994 A

  In the above prior art, it is necessary to provide the CPU of the apparatus main body with a function for monitoring whether the logic of the data signal line is inverted for a certain time in the power saving mode. Electricity was consumed as much as it was, and the power saving effect was small.

 The present invention has been made in view of the above-described circumstances, and an object thereof is to realize further reduction in power consumption of an image forming apparatus equipped with an optional device.

 In order to solve the above-described problems, in the present invention, as a first solving means related to an image forming apparatus, an apparatus main body that forms an image on printing paper and one or more optional devices attached to the apparatus main body are provided. In the image forming apparatus, the apparatus main body includes a main body control unit that controls an image forming operation of the apparatus main body, and the optional device controls the operation of the optional device according to an instruction from the main body control unit. The main body control unit and the option control unit are connected via a serial communication line, and at least the option control unit of the serial communication line is in a communicable state. A communication preparation signal line used to notify the control unit is connected to an interrupt terminal of the main body control unit, and the option control unit When notifying the main body control unit of the status change of the optional device when the body control unit is in the power saving mode, the potential of the communication preparation signal line is changed, and the main body control unit is configured to prepare for the communication in the power saving mode. When a change in the potential of the signal line is detected as an interrupt input, means for returning from the power saving mode to the normal operation mode is adopted.

  According to the present invention, as the second solving means related to the image forming apparatus, in the first solving means, the main body control unit is a communication partner of the serial communication lines in the power saving mode. When the potential of a selection signal line used for selecting the option control unit is held in a non-selected state, and the option control unit notifies the main body control unit of a state change of the option device, the selection signal line A means is adopted in which the main body control unit determines that it is in the power saving mode and changes the potential of the communication preparation signal line based on the fact that the potential is not selected.

  According to the present invention, as a third solving means relating to the image forming apparatus, in the first or second solving means, the main body control unit interrupts a potential change of the communication preparation signal line in the power saving mode. After detecting as an input and returning from the power saving mode to the normal operation mode, the potential of the selection signal line is changed to sequentially select option control units of all option devices as communication partners, and for each selected option control unit In this case, a means for searching for an option control unit in which the potential of the communication preparation signal line is changed is employed.

In the present invention, when the option control unit notifies the main unit control unit in the power saving mode of the status change of the optional device, the main unit control unit changes the potential of the communication preparation signal line included in the serial communication line. When the potential change of the communication preparation signal line is detected as an interrupt input, the power saving mode returns to the normal operation mode.
In other words, according to the present invention, the main body control unit can continue the power saving mode until it detects a potential change of the communication preparation signal line as an interrupt input, and performs extra processing during the power saving mode as in the prior art. Since this is not necessary, it is possible to realize further reduction in power consumption of the image forming apparatus to which the optional device is attached.

FIG. 2 is a front perspective view illustrating a main configuration of the printer 1 according to the present embodiment. It is a figure which shows the connection state by the serial communication line 30 of main body CPU16 and option CPU24 (24A, 24B).

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a front perspective view showing the main configuration of the printer 1 according to the present embodiment. As shown in FIG. 1, a printer 1 is an apparatus main body 10 that prints (forms) an image on printing paper and outputs it as a printed matter, and an optional apparatus that is mounted in four layers below the apparatus main body 10. It consists of feeders 20A, 20B, 20C and 20D. In the following description, the feeder code is set to 20, especially when it is not necessary to separate the feeder code from 20A, 20B, 20C, and 20D.

The apparatus main body 10 includes a paper feeding unit 11, a paper transporting unit 12, a toner image forming unit 13, a fixing unit 14, and a paper discharge tray 15.
The paper feeding unit 11 supplies printing paper to the toner image forming unit 13, and picks up the paper cassette 11a that stores printing paper of a predetermined size and the printing paper one by one from the paper cassette 11a. And a pickup roller 11b for feeding to a sheet conveyance path 12a described later. The paper cassette 11a can be inserted and removed from the front of the printer 1 by a slide mechanism including a guide rail.

  The paper transport unit 12 transports the printing paper supplied from the paper supply unit 11 to the paper discharge tray 15 via the toner image forming unit 13 and the fixing unit 14 and is formed by a guide member or the like. The sheet transport path 12a is provided, and transport rollers 12b are provided at a plurality of locations along the sheet transport path 12a. As will be described later, printing paper supplied from feeders 20A, 20B, 20C, and 20D, which are optional devices, also joins the paper transport path 12a.

  The toner image forming unit 13 responds to the image to be printed on the printing paper fed and fed through the paper feeding path 12a from the paper feeding unit 11 (or any of the feeders 20A, 20B, 20C, and 20D). A toner image is formed, and includes a photosensitive drum 13a, a charger 13b, an exposure device 13c, a developing device 13d, and a transfer roller 13e.

  The photoconductor drum 13a is a cylindrical photoconductor that forms an electrostatic latent image corresponding to an image to be printed and carries a developed toner image. The charger 13b uniformly charges the surface of the photosensitive drum 13a to a predetermined potential. The exposure device 13c forms an electrostatic latent image by irradiating the surface of the charged photosensitive drum 13a with laser light.

  The developing device 13d supplies toner to the photosensitive drum 13a on which the electrostatic latent image is formed, thereby developing the electrostatic latent image into a toner image. The transfer roller 13e transfers the toner image carried on the photosensitive drum 13a to the printing paper. A nip is formed between the transfer roller 13e and the photosensitive drum 13a, and the toner image on the surface of the photosensitive drum 13a is transferred to the printing paper when the printing paper passes through the nip.

  The fixing unit 14 fixes the toner image on the printing paper by heating and pressing the printing paper conveyed from the toner image forming unit 13 through the paper conveyance path 12a, that is, the printing paper on which the toner image is transferred. There is a heating roller 14a and a pressure roller 14b that presses against the heating roller 14a to form a nip. When the printing paper passes through the nip formed between the heating roller 14a and the pressure roller 14b, the toner image on the surface of the printing paper is heated and pressurized, and the toner image is fixed on the printing paper. .

  The paper discharge tray 15 is a part for storing the print paper discharged and conveyed from the fixing unit 14 through the paper conveyance path 12a, that is, the print paper after fixing the toner image as a printed matter on which a desired image is printed. The upper part of the apparatus main body 10 is provided.

  Each of the feeders 20A, 20B, 20C, and 20D is an optional device that supplies printing paper of different sizes to the apparatus main body 10. Each of the feeders 20A, 20B, 20C, and 20D includes a paper cassette 21 that stores printing paper of a predetermined size and printing paper from the paper cassette 21. Are picked up one by one, and a feed roller 23 that conveys the picked-up printing paper to the paper conveyance path 12a on the apparatus main body 10 side.

  When paper is fed from the lower feeder 20 to the apparatus main body 10, the printing paper is conveyed to the apparatus main body 10 via the upper feeder 20. For example, the printing paper fed from the feeder 20C is finally conveyed to the apparatus main body 10 from the upper feeder 20B via the feeder 20A. In the present embodiment, the case where four feeders 20A, 20B, 20C, and 20D are mounted on the apparatus main body 10 is illustrated, but the number of feeders 20 is not limited to this.

  Although not shown in FIG. 1, the apparatus main body 10 includes a main body CPU (Central Processing Unit) 16 that is a main body control unit that controls an image forming operation of the apparatus main body 10, and feeders 20 </ b> A, 20 </ b> B, and 20 </ b> C. And 20D are each provided with an option CPU 24 which is an option control unit for controlling the operation of the own apparatus in accordance with an instruction from the main body CPU 16.

  Here, the image forming operation of the apparatus main body 10 controlled by the main body CPU 16 includes a paper feeding operation by the paper feeding unit 11, a paper conveying operation by the paper conveying unit 12, a toner image forming operation by the toner image forming unit 13, And a fixing operation by the fixing unit 14. Further, the operation of the own apparatus (feeder 20) controlled by the option CPU 24 refers to a printing paper feeding operation by the rotation of the pickup roller 22 and the feed roller 23.

  As shown in FIG. 2, the main body CPU 16 and the option CPU 24 are communicably connected via a serial communication line 30. In FIG. 2, the option CPUs 24 of the feeders 20A and 20B are denoted by 24A and 24B, and the connection state between the option CPUs 24A and 24B and the main body CPU 16 is illustrated, but the option CPU 24 and the main body CPU 16 of the feeders 20C and 20D are illustrated. The connection state is also the same (not shown). Further, in the following description, the option CPU code is 24, especially when it is not necessary to separate the option CPU code from 24A and 24B.

  The first to third from the left end of the connector C1 for electrically connecting the main body CPU 16 and the option CPU 24A are used for selecting the option CPU 24 that the main body CPU 16 is a communication partner of the serial communication lines 30. Three select signal lines SEL2, SEL1, and SEL0 (selection signal lines) are connected.

  These select signal lines SEL2, SEL1, and SEL0 are connected to the select signal output port of the main body CPU 16, and the main body CPU 16 sets the potentials of the select signal lines SEL2, SEL1, and SEL0 to a high level (logic “1”) or The option CPU 24 to be a communication partner is selected by changing to a low level (logic “0”).

  For example, when the main body CPU 16 selects the option CPU 24A as a communication partner, the potentials of the select signal lines SEL0 and SEL1 are set to a low level (ie, “0”), and the potential of the select signal line SEL2 is set to a high level (ie, “1”). And That is, when the logic is viewed in the order of SEL2 → SEL1 → SEL0, “1, 0, 0” is obtained. Similarly, when the option CPU 24B is selected as the communication partner, the logic becomes “1, 1, 0” in the order of SEL2 → SEL1 → SEL0.

  Here, there are eight combinations of logic using the three select signal lines SEL2, SEL1, and SEL0. Therefore, a state in which all the potentials of the select signal lines SEL2, SEL1, and SEL0 are at a low level (logic combination is “0, 0, 0”) is defined as a state in which no communication partner is selected, that is, a non-selected state. Therefore, a communication partner can be selected from a maximum of seven option CPUs 24. As a combination of logic, “1, 0, 1” or “0, 1, 0” may be defined as a non-selected state.

  The select signal lines SEL2, SEL1, and SEL0 are connected to the select signal input port of the option CPU 24A. The option CPU 24A is based on the potential (that is, the combination of logic) of each select signal line SEL2, SEL1, and SEL0. Then, it is determined whether or not the communication partner is selected.

  On the other hand, in the connector C2 for electrically connecting the main body CPU 16 and the next-stage option CPU 24B, the select signal lines SEL2, SEL1, and SEL0 are connected at different positions. Specifically, the select signal line SEL0 at the previous stage is at the position of the select signal line SEL1 at the next stage, the select signal line SEL1 at the previous stage is at the position of the select signal line SEL2 at the next stage, and the select signal line SEL2 at the previous stage is These are rearranged to the position of the select signal line SEL0 in the next stage. An inverter circuit Inv is connected to the select signal line SEL2 at the previous stage, and the potential of the select signal line SEL0 at the next stage is inverted with respect to the select signal line SEL2 at the previous stage.

  When the selection signal lines SEL2, SEL1, and SEL0 are rearranged (circulated) between the upstream and downstream feeders 20, each option CPU 24 determines whether it is selected as a communication partner. The combination of logic can be unified. For example, if the logic when the option CPU 24A is selected as the communication partner is “1, 0, 0” and the logic when the option CPU 24B is selected is “1, 1, 0” as described above, In both the CPUs 24 </ b> A and 24 </ b> B, the combination of logic that determines that the CPU 24 </ b> A and 24 </ b> B is selected as the communication partner is unified to “1, 0, 0”. Therefore, the control program for the option CPU 24 can be shared.

  The ready signal line RDY (communication preparation signal line) used to notify the main body CPU 16 that the option CPU 24 is in a communicable state is connected to the fourth from the left end of the connector C1. ing. The ready signal line RDY is connected to an interrupt input port (interrupt terminal) of the main body CPU 16, and is connected to a ready signal output port of the option CPU 24A. The ready signal line RDY is connected to the connector C2 from the connector C1 at the same position.

  For example, when the option CPU 24A determines that it is selected as a communication partner from the potentials (that is, combinations of logics) of the select signal lines SEL2, SEL1, and SEL0, it becomes possible to communicate with the main body CPU 16. Then, the potential of the ready signal line RDY is changed from the low level to the high level to notify the main body CPU 16 that the communication is possible. When the main body CPU 16 detects a change in the potential of the ready signal line RDY, the main body CPU 16 recognizes that the option CPU 24A selected as the communication partner is in a communicable state and starts communication. The same applies to the option CPU 24B in the next stage.

  A data signal line SDI through which the main body CPU 16 receives data from the option CPU 24 is connected to the fifth from the left end of the connector C1. Further, a data signal line SDO for transmitting data from the main body CPU 16 to the option CPU 24 is connected to the sixth from the left end of the connector C1. Further, the seventh clock from the left end of the connector C1 is connected to a clock signal line CLK for sharing and synchronizing the clock signal between the main body CPU 16 and the option CPU 24 among the serial communication lines 30. The data signal lines SDI and SDO and the clock signal line CLK are connected from the connector C1 to the connector C2 as they are.

  For example, when the main body CPU 16 detects a change in the potential of the ready signal line RDY and recognizes that the option CPU 24A selected as the communication partner is in a communicable state, it synchronizes with the rise of the clock signal flowing through the clock signal line CLK. Data is transmitted via the data signal line SDO. On the other hand, the option CPU 24A latches data on the data signal line SDO in synchronization with the fall of the clock signal flowing through the clock signal line CLK.

  Conversely, when data is transmitted from the option CPU 24A to the main body CPU 16, the option CPU 24A transmits data via the data signal line SDI in synchronization with the rise of the clock signal, while the main body CPU 16 is at the fall of the clock signal. In synchronization, the data on the data signal line SDI is latched. The same applies to the option CPU 24B in the next stage.

  Next, the operation in the power saving mode of the printer 1 configured as described above will be described. When no print instruction is received from an external device (for example, a personal computer) for a certain period of time, the main body CPU 16 switches to a power saving mode in which only a limited function operates in order to minimize the power consumption of the printer 1. At this time, the main body CPU 16 also stops the communication function with the option CPU 24, and therefore cannot recognize the state change of each feeder 20 (for example, completion of replenishment of printing paper).

  In order for the main body CPU 16 and the option CPU 24 to communicate, it is necessary to return the main body CPU 16 from the power saving mode to the normal operation mode. Therefore, in this embodiment, the option CPU 24 changes the potential of the ready signal line RDY from the low level to the high level when the main body CPU 16 notifies the main body CPU 16 of a change in the state of the device itself when the main body CPU 16 is in the power saving mode. When the main body CPU 16 detects a potential change of the ready signal line RDY as an interrupt input in the power saving mode, the main body CPU 16 returns from the power saving mode to the normal operation mode.

  Here, since the option CPU 24 cannot determine whether the main body CPU 16 is currently in the power saving mode or the normal operation mode, for example, when the main body CPU 16 is communicating with another option CPU 24, the potential of the ready signal line RDY is changed. If this happens, communication between the main body CPU 16 and the other option CPU 24 will be hindered.

  Therefore, in the present embodiment, the main body CPU 16 holds the potentials of the select signal lines SEL2, SEL1, and SEL0 (that is, combinations of logic) in a non-selected state (for example, “0, 0, 0”) in the power saving mode. When the option CPU 24 notifies the main body CPU 16 of the state change of its own device, the main body CPU 16 is in the power saving mode because the potentials of the select signal lines SEL2, SEL1, and SEL0 are not selected. And the potential of the ready signal line RDY is changed.

  Thereby, when the main body CPU 16 is communicating with another option CPU 24 (in the normal operation mode), it is possible to prevent the communication between the main body CPU 16 and the other option CPU 24 from being hindered. Further, when the main body CPU 16 is in the power saving mode, the power saving mode can be continued until the potential change of the ready signal line RDY is detected as an interrupt input, and it is necessary to perform extra processing during the power saving mode as in the prior art. Therefore, it is possible to further reduce the power consumption of the printer 1 to which the feeder 20 as an optional device is attached.

  Note that the main body CPU 16 cannot recognize which option CPU 24 has changed the potential of the ready signal line RDY when returning to the normal operation mode. Therefore, the main body CPU 16 detects the potential change of the ready signal line RDY as an interrupt input in the power saving mode and returns to the normal operation mode from the power saving mode, and then changes the potential of each select signal line SEL2, SEL1, and SEL0. All option CPUs 24 are sequentially selected as communication partners, and communication is performed for each selected option CPU 24 to search for the option CPU 24 in which the potential of the ready signal line RDY is changed.

As mentioned above, although one Embodiment of this invention was described, this invention is not limited to this, Of course, it can change variously in the range which does not deviate from the meaning of this invention.
For example, in the above embodiment, the printer 1 has been described as an example of the image forming apparatus according to the present invention. However, the present invention is not limited to this, and a multifunction machine having functions such as a copier, a printer, a scanner, a facsimile, The present invention can be widely applied to image forming apparatuses to which other optional devices can be attached.

 DESCRIPTION OF SYMBOLS 1 ... Printer (image forming apparatus), 10 ... Apparatus main body, 20, 20A, 20B, 20C, 20D ... Feeder (optional apparatus), 16 ... Main body CPU (main body control part), 24, 24A, 24B ... Optional CPU (option) Control unit), 30 ... serial communication line, SEL0, SEL1, SEL2 ... select signal line (selection signal line), RDY ... ready signal line (communication preparation signal line)

Claims (3)

In an image forming apparatus comprising an apparatus main body for forming an image on printing paper and one or more optional devices mounted on the apparatus main body,
The apparatus main body includes a main body control unit that controls an image forming operation of the apparatus main body,
The optional device includes an option control unit that controls the operation of the optional device in accordance with an instruction from the main body control unit,
The main body control unit and the option control unit are connected via a serial communication line, and notify the main body control unit that the option control unit is in a communicable state at least among the serial communication lines. A communication preparation signal line used for connecting to the interrupt terminal of the main body control unit,
When the main body control unit notifies the main body control unit of a change in state of the optional device when the main body control unit is in a power saving mode, the potential of the communication preparation signal line is changed,
When the main body control unit detects a change in potential of the communication preparation signal line as an interrupt input during the power saving mode, the main body control unit returns to the normal operation mode from the power saving mode.
An image forming apparatus. The main body control unit holds a potential of a selection signal line used for selecting the option control unit to be a communication partner among the serial communication lines in the power saving mode in a non-selected state,
When the option control unit notifies the main body control unit of a status change of the optional device, the main body control unit is in a power saving mode because the potential of the selection signal line is in a non-selected state. The image forming apparatus according to claim 1, wherein the potential of the communication preparation signal line is changed based on the determination.   The main body control unit detects a change in potential of the communication preparation signal line as an interrupt input in the power saving mode, and after returning from the power saving mode to the normal operation mode, changes the potential of the selection signal line to The option control unit of the optional device is sequentially selected as a communication partner, and communication is performed for each selected option control unit, thereby searching for an option control unit in which the potential of the communication preparation signal line is changed. The image forming apparatus according to claim 1.

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