JP6451068B2 - Facsimile machine and option unit - Google Patents

Description

The present invention relates to a facsimile device and optional units.

  There is known a configuration in which a user can arbitrarily add a sheet feeding cassette (sheet feeding unit) as an optional unit to a main body of a multifunction machine or the like having a facsimile function, a copy / print function, and the like. A driving voltage is supplied to the sheet feeding unit from the main body side. However, if an inrush current occurred in each option unit at the same timing when the power was turned on, the current value output from the main body side was temporarily excessive due to the total inrush current, and the burden on the main body side was heavy.

  The IP phone terminal and each option unit are provided with a switch and a timing generation circuit having different time constants. When the power is turned on, the drive power supply timing to the load circuit in each unit is set between the IP phone terminal and each option unit. A configuration for shifting is disclosed (see Patent Document 1).

JP 2006-199886 A

  As described in Document 1, in order to shift the drive power supply timing to the load circuit in each unit, each option unit needs to have a timing generation circuit having different time constants. For this reason, it is impossible to meet the demand to increase the production efficiency by mass-producing optional units with the same specifications as much as possible.

  Although it is conceivable for the user to change the time constant for each option unit by providing a variable resistor in the timing generation circuit, the operation is complicated for the user and there is a possibility that an incorrect setting is made.

The present invention has been made to solve at least one of the above-mentioned problems, to provide a facsimile apparatus and option units suppressed the adverse effects of inrush current.

One aspect of the present invention is a scanner unit that reads an original to generate image data, a facsimile unit that can execute transmission / reception of image data using a facsimile standard, and a sheet supplied with an image based on the image data. A facsimile apparatus comprising: a main unit including a printing unit; and a paper feeding unit for supplying the paper,
One or more paper feeding units are mounted, and a power feeding unit that receives electricity from the main body or the upper paper feeding unit, a power distribution unit that distributes electricity to a lower paper feeding unit, and power feeding from the power feeding unit A motor that operates with electricity, a notification unit that notifies power reception permission to the reception unit of the lower paper feed unit, a reception unit that receives power supply permission from the notification unit of the main body unit or upper paper feed unit, A control unit that causes the power supply unit to start power supply when the reception unit accepts the power supply permission, and causes the notification unit to notify the power supply permission when a supplied voltage exceeds a predetermined threshold, and stores The supplied sheet or the sheet supplied from the lower sheet feeding unit is supplied to the upper sheet feeding unit or the printing unit by the power generated by the motor.

  According to the present invention, electricity (electric power, current, charge) is supplied from the uppermost sheet feeding unit to the lowermost sheet feeding unit via the power feeding unit and the power distribution unit of each sheet feeding unit. On the other hand, the control unit starts power feeding from the power feeding unit to the motor side in response to acceptance of power feeding permission from the upper side by the receiving unit, and in response to the voltage by this power feeding exceeding a predetermined threshold value Then, the notification unit notifies the reception unit of the lower sheet feeding unit of the power supply permission. For this reason, the timing at which power feeding from the power feeding unit to the motor side is started differs for each paper feeding unit, and the generation timing of the inrush current for each paper feeding unit does not overlap. Further, according to the present invention, it is possible to obtain an effect of shifting the generation timing of the inrush current for each paper feed unit only by mounting a plurality of paper feed units having the same configuration in the facsimile apparatus. Therefore, the problem assumed in the document 1 can be solved.

In one aspect of the present invention, the control unit includes a switch interposed between the power feeding unit and the motor, and the switch is turned on in response to acceptance of the power feeding permission by the receiving unit, and the switch May cause the notification unit to notify the permission of power supply in response to the voltage supplied to the motor side exceeding the threshold.
According to this configuration, since the timing at which the switch is turned on is shifted for each paper feed unit, it is possible to avoid the occurrence of inrush currents for each paper feed unit from overlapping.

In one aspect of the present invention, the control unit includes a capacitor having one end connected between the switch and the motor and the other end connected to a ground terminal, and the switch and the one end of the capacitor. A Zener diode having a cathode connected therebetween, a bipolar transistor having a base connected to the anode side of the Zener diode, a collector connected to the notification unit, and an emitter connected to a ground terminal, the switch comprising: The receiving unit is connected to the gate of the MOSFET, and the MOSFET switches from a non-conducting state to a conducting state according to a difference between a voltage at the power feeding unit and a voltage at which the receiving unit accepts the power feeding permission. By switching, the power supply part passes between the source and drain of the MOSFET and enters the motor side. A charge is stored in the capacitor by the current that is applied, and the Zener diode breaks down in response to an increase in the voltage supplied to the motor side, and after the breakdown, the bipolar transistor switches from a non-conductive state to a conductive state. It is good also as the signal as the said electric power supply permission generate | occur | producing on the said collector side by changing.
According to this configuration, in each paper feed unit, the current (inrush current) that passes through the MOSFET from the power supply unit and is input to the motor side disappears when charging of the capacitor is finished, and such paper feed The inrush current for each unit is generated at a shifted timing.

As one aspect of the present invention, the control unit may provide resistors in all paths between the power feeding unit and the switch.
According to this configuration, since resistance is provided in all paths through which current can flow from the power supply unit to the parasitic capacitance existing in the switch, a type of inrush current called spike wave or the like may flow to the parasitic capacitance. It is suppressed.

  The technical idea of the present invention is not realized only by the above-described facsimile apparatus, but widely realized by an option unit connected to a power supply apparatus (for example, the main body), a system including the option unit, or the like. . As an example, an optional unit connected to a power supply device, a power supply unit that receives power from the power supply device or a higher option unit, a power distribution unit that distributes electricity to a lower option unit, and the power supply unit An operation unit that operates with electricity to be fed, a notification unit that notifies power reception permission to the reception unit of the lower option unit, a reception unit that receives power supply permission from the notification unit of the power supply device or the higher option unit, A configuration including a control unit that causes the power supply unit to start power supply when the reception unit receives the power supply permission, and that notifies the power supply permission to the notification unit when a voltage to be supplied exceeds a predetermined threshold; It can be grasped as one invention.

  An option unit control system comprising a power feeding device and an option unit connected to the power feeding device, wherein the power feeding device distributes electricity to the option unit having the highest connection, and A first notification unit for notifying the uppermost option unit of permission of power supply, and the option unit supplies power to the power supply unit or a higher-order option unit and a lower-order option unit. A second power distribution unit that distributes power, an operation unit that operates with electricity supplied from the power supply unit, a second notification unit that notifies the reception unit of the lower option unit of power supply permission, and the power supply device or the upper unit An accepting unit that accepts the power supply permission of the option unit, and power supply to the power supply unit when the accepting unit accepts the power supply permission. Is started, the configuration voltage fed is provided with a control unit for notifying the feed permission to the second notification unit exceeds a predetermined threshold, it can be regarded as one invention.

  The system may exist in a single independent product or may exist across multiple products. In addition, the invention of each method including processing steps corresponding to each of the facsimile machine, the option unit, the power feeding device (for example, the main body), and the system, and the hardware (computer) execute each process step. The present invention may be realized in various categories such as a computer program and a computer-readable recording medium on which the program is recorded.

It is a figure showing roughly the device composition concerning this embodiment. It is a figure which illustrates 1st Embodiment. It is a figure which illustrates the change with respect to time of a voltage and an electric current. It is a figure which illustrates 2nd Embodiment. It is a figure which illustrates 3rd Embodiment. It is a figure which illustrates 4th Embodiment. It is a figure which illustrates 5th Embodiment.

Embodiments of the present invention will be described in the following order.
1. 1. Outline of device configuration 1. First embodiment Second Embodiment 4. 3. Third embodiment 4. Fourth embodiment Fifth embodiment Other embodiments

1. FIG. 1 schematically shows a configuration of a facsimile machine 10 according to the present embodiment. The facsimile machine 10 is also called a multifunction machine 10. The multifunction machine 10 has a main body 11. The main body 11 includes, for example, a power supply circuit 12, a power distribution circuit 13, a facsimile unit 20, a scanner unit 30, and a printing unit 40. Further, the multifunction machine 10 is equipped with one or more paper feed units 50 as a kind of “optional unit” that can be added by the user to the main body 11. The paper feed unit 50 may be called a paper feed cassette or the like. FIG. 1 shows an example in which three paper feeding units 50 are mounted.

  The paper feed unit 50A closest to the printing unit 40 when installed in the multifunction machine 10 is the paper feed unit 50A, and the paper feed unit 50 one level lower than the paper feed unit 50A is the paper feed unit 50B. The paper feed unit 50 that is one level lower than the paper feed unit 50B is also referred to as a paper feed unit 50C. The sheet feeding unit 50 may be further added at a position lower than the sheet feeding unit 50C (see the position indicated by the broken-line rectangle in FIG. 1). In this embodiment, when referring to the upper and lower positions between the paper feeding units 50 in relation to the printing unit 40, the one closer to the printing unit 40 is regarded as the higher order, but does not necessarily mean the vertical direction in the vertical direction. . Further, as will be described later, regarding the positional relationship between the paper feeding units 50 connected in series to the power distribution circuit 13, the side closer to the power distribution circuit 13 is regarded as the upper level.

  In the main body 11, the power supply circuit 12 performs transformation, AC / DC conversion, or the like on the AC voltage input from the AC plug 14, thereby obtaining a predetermined level (for example, a voltage for driving each load). DC of about 42 V) is generated and output to the power distribution circuit 13. The power distribution circuit 13 supplies the voltage output from the power supply circuit 12 to each load such as the facsimile unit 20, the scanner unit 30, the printing unit 40, and the paper feeding unit 50.

  The facsimile unit 20 includes a modem connected to a facsimile communication line (not shown), and can transmit and receive image data using a predetermined facsimile standard. The facsimile unit 20 receives image data transmitted from the outside via the communication line, decompresses the received image data, and compresses the image data generated by reading by the scanner unit 30 or image data after compression. Facsimile transmission to the outside via the communication line.

  The scanner unit 30 reads an original set on an original table, an ADF (Auto Document Feeder) or the like with an optical sensor, and generates image data (for example, bitmap data) of the original. The image data generated by the scanner unit 30 is a target of printing by the printing unit 40 or a target of facsimile transmission by the facsimile unit 20 as described above.

  The printing unit 40 is a unit (printing engine) that prints an image on a sheet using a color material such as ink or toner. The printing unit 40 receives image data received and decompressed by the facsimile unit 20, image data generated by the scanner unit 30, and other image data input sources (personal computer (PC) connected to the multifunction machine 10, Printing is performed based on image data received from a portable terminal, a digital still camera, or the like. A paper feed tray (not shown) may be provided in the printing unit 40. That is, the printing unit 40 performs printing on the paper accumulated in the paper feed tray of the printing unit 40 or the paper M supplied from the paper feeding unit 50. Therefore, the multifunction device 10 operates normally only with the main body 11 even if the paper feeding unit 50 is not installed. However, in the present embodiment, as described above, one or more paper feed units 50 are mounted on the multifunction machine 10.

  Each paper feed unit 50 basically has the same configuration (with exceptions), and includes a unit-side power control unit 51, a roller 57, and the like. The unit side power supply control unit 51 controls the operation of the roller 57 and the like by the supplied electricity. The paper feed unit 50 accumulates the paper M in a built-in tray, and supplies the paper M to the upper level by rotating a roller 57 by power generated by a motor 53 described later. In the example of FIG. 1, the lowermost paper feed unit 50C supplies the paper M stored therein to the upper paper feed unit 50B. The paper feed unit 50B supplies the paper M stored therein or the paper M supplied from the lower paper feed unit 50C to the upper paper feed unit 50A. The uppermost paper feed unit 50A supplies the printing unit 40 with the paper M stored therein or the paper M supplied from the lower paper feed unit 50B. In FIG. 1, the flow of the sheet M is illustrated by a dashed arrow (refer to Japanese Patent Laid-Open No. 2002-255382 as appropriate).

  In the following, the unit-side power control unit 51 provided in the paper feed unit 50A is provided as a unit-side power control unit 51A, and the unit-side power control unit 51 provided in the paper feed unit 50B is provided as a unit provided in the unit-side power control unit 51B and the paper feed unit 50C. The side control power source control unit 51 is also referred to as a unit side power source control unit 51C. The multifunction device 10 has a display unit (liquid crystal panel or the like) and an operation unit (buttons, keys, touch panel, etc.) (not shown) that receive various instructions from the user or present the state of the multifunction device 10 to the user. It is good. The multifunction machine 10 may have a call (telephone) function.

2. 1st Embodiment Based on the above-mentioned structure, 1st Embodiment for delaying the generation | occurrence | production timing of an inrush current for every option unit is described.
FIG. 2 exemplifies a connection mode between the unit-side power control units 51. The unit-side power control unit 51 has an input terminal (“T1” for the unit-side power control unit 51A, “T11” for the unit-side power control unit 51B, “T21” for the unit-side power control unit 51C. "Hereinafter, the same writing method is used as appropriate.), Input terminals (S1, S11, S21), output terminals (T2, T12, T22), and output terminals (S2, S12, S22). Further, the distribution line L0 extends from the distribution circuit 13 of the main body 11, and the tip of the distribution line L0 branches to the output terminals T0 and S0.

  As shown in FIG. 1, when the paper feeding units 50A, 50B, and 50C are added to the main body 11, the input terminal T1 provided in the unit-side power control unit 51A of the uppermost paper feeding unit 50A is connected to the output terminal T0. The input terminal S1 is connected to the output terminal S0. Similarly, the input terminal T11 provided in the unit-side power control unit 51B of the paper feed unit 50B is connected to the output terminal T2 provided in the unit-side power control unit 51A, and the input terminal S11 provided in the unit-side power control unit 51B of the paper feed unit 50B. Are respectively connected to the output terminal S2 provided in the unit-side power control unit 51A. The input terminal T21 provided in the unit-side power control unit 51C of the paper feed unit 50C is connected to the output terminal T12 provided in the unit-side power control unit 51B, and the input terminal S21 provided in the unit-side power control unit 51C of the paper feed unit 50C is used as the unit side. Each is connected to an output terminal S12 included in the power supply control unit 51B.

  In the unit-side power control unit 51, the input terminals (T1, T11, T21) are connected to the feeder lines (L1, L11, L21), and the feeder lines (L1, L11, L21) are connected to the distribution line (L3, L3). Branching to L13, L23). Furthermore, the distribution lines (L3, L13, L23) are connected to the output terminals (T2, T12, T22). Therefore, when the distribution circuit 13 outputs the voltage of, for example, 42V to the distribution line L0, the distribution line L0, the output terminal T0, the input terminal T1, the feeder line L1, the distribution line L3, the output terminal T2, the input terminal T11, the supply line Electricity is supplied to each unit-side power supply control unit 51 through a continuous path of the electric wire L11, the distribution line L13, the output terminal T12, the input terminal T21, the feeder line L21,.

  In the unit-side power control unit 51, the power supply lines (L1, L11, L21) are connected to the sources of MOSFETs (QF1, QF11, QF21) as switches through resistors (R2, R12, R22) The drains of (QF1, QF11, QF21) are connected to the output signal lines (L2, L12, L22). MOSFET is a kind of field effect transistor. In addition, current limiting units (62A, 62B, 62C) including resistors (R2, R12, R22) are provided between the feeder lines (L1, L11, L21) and the MOSFETs (QF1, QF11, QF21). Yes.

  The current limiter (62A, 62B, 62C) is a connection point (first connection) between the input terminal (T1, T11, T21) of the feeder line (L1, L11, L21) and the resistor (R2, R12, R22). And a PNP bipolar transistor (Q1, Q11, Q21) having an emitter connected via a resistor (R1, R11, R21). The transistor (Q1, Q11, Q21) has a base connected to a connection point (second connection point) between the resistor (R2, R12, R22) and the source of the MOSFET (QF1, QF11, QF21), and a collector connected to the MOSFET It is connected to the gates of (QF1, QF11, QF21). Resistors (R3, R13, R23) are provided between the bases of the transistors (Q1, Q11, Q21) and the second connection point, and the collectors of the transistors (Q1, Q11, Q21) and MOSFETs (QF1, QF11, QF21). ) Are provided with resistors (R4, R14, R24). The function (current limiting function) of such a current limiting unit (62A, 62B, 62C) will be described later.

  In the unit-side power control unit 51, the output signal lines (L 2, L 12, L 22) are connected to the motor drive units 52 provided in the respective paper feed units 50. The motor driving unit 52 is a circuit that controls the driving of the motor 53 for rotating the roller 57. The motor 53 corresponds to an example of an “operation unit” in the claims.

  In the unit-side power control unit 51, the input terminals (S1, S11, S21) are connected to the gates of the MOSFETs (QF1, QF11, QF21). However, in the first embodiment, among the unit-side power control units 51, only the unit-side power control unit 51A of the uppermost sheet feeding unit 50A is switched between the input terminal S1 and the gate of the MOSFET QF1. A delay unit 60A and a switch driving unit 61A are provided. As will be described later, the switch drive delay unit 60A and the switch drive unit 61A are circuits that control the drive timing of the switch (MOSFET QF1) included in the unit-side power supply control unit 51A.

  In the unit-side power control unit 51, the output signal lines (L2, L12, L22) are branched to the signal lines (L4, L14, L24). For the output signal lines (L2, L12, L22), electrolytic capacitors (C1, C11, C21) are provided between the branch points to the signal lines (L4, L14, L24) and the motor drive unit 52. One end is connected, and the electrolytic capacitor (C1, C11, C21) has the other end connected to the ground terminal. The ground terminal is grounded directly or indirectly.

  In the unit-side power control unit 51, the switch drive delay units (63A, 63B, 63C) are connected to the signal lines (L4, L14, L24), and the subsequent stage of the switch drive delay units (63A, 63B, 63C). Is connected to a switch drive section (64A, 64B, 64C). Further, the subsequent stage of the switch drive unit (64A, 64B, 64C) is connected to the notification line (L5, L15, L25). The notification lines (L5, L15, L25) are connected to the output terminals (S2, S12, S22).

  In the switch drive delay units (63A, 63B, 63C), the Zener diodes (Z1, Z11, Z21) have their cathodes connected to the branch point side with the output signal lines (L2, L12, L22). On the other hand, two resistors (R5 and R6, R15 and R16, R25 and R26) are connected in series between the anode of the Zener diode (Z1, Z11, Z21) and the ground terminal. Between the two resistors (between the resistor R5 and the resistor R6, between the resistor R15 and the resistor R16, and between the resistor R25 and the resistor R26), an NPN bipolar transistor (Q2, Q12, Q22) The base is connected. A capacitor (C2, C12, C22) has one end connected between the resistor (R5, R15, R25) and the base of the transistor (Q2, Q12, Q22), and the capacitor (C2, C12, C22). ) Is connected to the ground terminal. The switch drive delay units (63A, 63B, 63C) include such Zener diodes (Z1, Z11, Z21), resistors (R5, R15, R25), resistors (R6, R16, R26) and capacitors (C2, C12, C22) is included in whole or in part.

  In the switch driver (64A, 64B, 64C), the transistors (Q2, Q12, Q22) have their collectors connected to the notification lines (L5, L15, L25) via resistors (R7, R17, R27). The emitter is connected to the ground terminal. Further, one end of the resistor (R8, R18, R28) is connected to the notification line (L5, L15, L25), and the other end of the resistor (R8, R18, R28) is connected to the distribution line (L3). , L13, L23). The switch drive unit (64A, 64B, 64C) includes all or part of such transistors (Q2, Q12, Q22), resistors (R7, R17, R27) and resistors (R8, R18, R28). Has been.

  The switch drive delay unit 63A and the switch drive unit 64A included in the unit side power control unit 51A of the paper feed unit 50A control the drive timing of the switch (MOSFETQF11) included in the unit side power control unit 51B of the lower paper feed unit 50B. It is a circuit and corresponds to a part of the “control unit” in the claims. Similarly, the switch drive delay unit 63B and the switch drive unit 64B included in the unit-side power control unit 51B of the paper feed unit 50B are the drive timings of the switches (MOSFETQF21) included in the unit-side power control unit 51C of the lower paper feed unit 50C. Is a circuit (a part of the control unit). Similarly, the switch drive delay unit 63C and the switch drive unit 64C included in the unit-side power control unit 51C of the paper feed unit 50C are used to drive switches (MOSFETs) included in the unit-side power control unit 51 of the lower paper feed unit 50. It is a circuit (a part of the control unit) that controls timing.

  Note that the switch drive delay unit 60A and the switch drive unit 61A included in the unit-side power supply control unit 51A of the uppermost sheet feeding unit 50A also have a circuit configuration of the switch drive delay unit 63A, the switch drive unit 64A, and the switch drive delay unit 63B. The switch drive unit 64B, the switch drive delay unit 63C, and the switch drive unit 64C are the same.

  That is, in the switch drive delay unit 60A of the unit-side power control unit 51A, the Zener diode Z0 connects the cathode to the input terminal S1. The anode of the Zener diode Z0 is connected to the base of the NPN bipolar transistor Q0 via the resistor R02. Further, one end of each of the capacitor C0 and the resistor R03 is connected between the resistor R02 and the base of the transistor Q0, and the other end of each of the capacitor C0 and the resistor R03 is connected to the ground terminal. In the switch drive unit 61A of the unit-side power control unit 51A, the transistor Q0 has a collector connected to the gate of the MOSFET QF1 through the resistor R01 and an emitter connected to the ground terminal. Further, one end of the resistor R0 is connected between the resistor R01 and the MOSFET QF1, and the other end of the resistor R0 is connected between the input terminal T1 and the current limiting unit 62A in the feeder line L1.

The operation of the circuit shown in FIG. 2 will be described.
When electricity is distributed from the distribution circuit 13 as described above, first, in the unit-side power control unit 51A, when the voltage input from the input terminal S1 rises to a predetermined level (via the distribution line L0 and the output terminal S0). The zener diode Z0 breaks down and a current flows from the cathode to the anode side. As a result, a voltage corresponding to the ratio of the resistors R02 and R03 is generated between the base and emitter of the transistor Q0, and the transistor Q0 is switched from the non-conductive (off) state to the conductive (on) state. Capacitor C0 stabilizes the switching operation of transistor Q0 to the on state or delays the switching timing.

  When the transistor Q0 is turned on, a current flows from the input terminal T1 through the resistors R0 and R01 to the transistor Q0, and a voltage corresponding to the ratio of the resistors R0 and R01 is applied between the gate and the source of the MOSFET QF1. Switches from off to on. That is, after the input terminals S1 and T1 input the voltage from the power distribution circuit 13, the MOSFET QF1 is driven with a certain delay by the functions of the switch drive delay unit 60A and the switch drive unit 61A (becomes turned on). . As a result, a current (inrush current IB1) flows from the input terminal T1 through the resistor R2 and between the source and drain of the MOSFET QF1 to the output signal line L2, and a voltage VB1 is generated in the output signal line L2. Charge is stored in the electrolytic capacitor C1 by the inrush current IB1, and when the electrolytic capacitor C1 is fully charged, the inrush current IB1 disappears. Thereafter, the voltage VB1 is stably applied to the motor drive unit 52 to which the output signal line L2 is connected, and the motor drive unit 52 controls the motor 53 using the applied voltage.

  The current limiting function by the current limiting unit (62A, 62B, 62C) will be described. Here, the current limiting unit 62A of the unit-side power control unit 51A will be described as an example, but the other current limiting units 62B and 62C also exhibit a similar current limiting function. When the MOSFET QF1 of the unit-side power control unit 51A becomes conductive as described above, a voltage is generated in the resistor R2 due to the current flowing through the feeder line L1. As a result, a voltage is generated between the base and emitter of the transistor Q1, and the transistor Q1 is turned on. When the transistor Q1 is turned on, a current flows from the input terminal T1 through a path passing through the resistor R1, the transistor Q1, and the resistor R4, and the amount of current flowing through the resistor R2 decreases as the current increases. When the amount of current flowing through the resistor R2 decreases, the transistor Q1 returns to the off state. Thereafter, the transistor Q1 is repeatedly turned on and off, so that the current flowing into the MOSFET QF1 through the resistor R2 is limited (equilibrium) below a certain level.

  The voltage VB1 is also applied to the switch drive delay unit 63A of the unit-side power control unit 51A via the signal line L4. That is, when the voltage VB1 rises to a predetermined level, the Zener diode Z1 breaks down. As a result, a voltage corresponding to the ratio of the resistors R5 and R6 is generated between the base and emitter of the transistor Q2, and the transistor Q2 is switched from the off state to the on state. Similar to the function of the capacitor C0, the capacitor C2 stabilizes the switching operation of the transistor Q2 and delays the switching timing. When the transistor Q2 is turned on, current flows from the input terminal T1 through the distribution line L3 and the resistors R8 and R7 to the transistor Q2, and a voltage corresponding to the ratio of the resistors R8 and R7 is generated on the notification line L5.

  The voltage generated in the notification line L5 in this way is a power supply permission (a signal that behaves as a power supply permission. Hereinafter, also referred to as a notification signal) to the lower paper feed unit 50B. The notification signal is applied to the gate of the MOSFET QF11 of the unit-side power supply control unit 51B via the notification line L5, the output terminal S2, and the input terminal S11. As a result, the MOSFET QF11 is switched from the off state to the on state due to the potential difference between the gate and the source (the difference between the voltage (42V) input through the input terminal T11 and the voltage of the notification signal input through the input terminal S11). Thereafter, operations similar to the operations after the MOSFET QF1 of the unit-side power control unit 51A is turned on sequentially occur.

  That is, in the unit-side power control unit 51B, when the MOSFET QF11 is turned on, a current (inrush current IB2) flows from the input terminal T11 through the resistor R12 and the MOSFET QF11 to the output signal line L12, and the voltage is applied to the output signal line L12. VB2 is generated. Charge is stored in the electrolytic capacitor C11 by the inrush current IB2, and the inrush current IB2 disappears when the electrolytic capacitor C11 is fully charged. Thereafter, the voltage VB2 is stably applied to the motor driving unit 52 connected to the output signal line L12. The voltage VB2 is also applied to the switch drive delay unit 63B of the unit-side power control unit 51B via the signal line L14. When the voltage VB2 rises to a predetermined level, the Zener diode Z11 breaks down. After that, when the transistor Q12 is turned on after a certain delay, a notification signal to the lower paper feed unit 50C is generated on the notification line L15. The notification signal is applied to the gate of the MOSFET QF21 of the unit-side power control unit 51C via the notification line L15, the output terminal S12, and the input terminal S21, whereby the MOSFET QF21 is switched from the off state to the on state.

  In the unit-side power controller 51C, when the MOSFET QF21 is turned on, a current (inrush current IB3) flows from the input terminal T21 through the resistor R22 and the MOSFET QF21 to the output signal line L22, and the voltage VB3 is applied to the output signal line L22. Occur. Charge is stored in the electrolytic capacitor C21 by the inrush current IB3, and when the electrolytic capacitor C21 is fully charged, the inrush current IB3 disappears. Thereafter, the voltage VB3 is stably applied to the motor drive unit 52 to which the output signal line L22 is connected. Even if the unit-side power control unit 51 is further connected to the lower side of the unit-side power control unit 51C, the same operation occurs in order.

  2, the input terminals (T1, T11, T21) correspond to power supply units that are supplied with electricity from the main body unit 11 or the upper sheet feeding unit 50, and output terminals (T2, T12). , T22) corresponds to a power distribution unit that distributes electricity to the lower paper feed unit 50. Further, the input terminals (S1, S11, S21) are allowed to supply power from the notification unit of the main body unit 11 or the upper sheet feeding unit 50 (voltage output from the distribution circuit 13 to the distribution line L0, or notification lines L5, L15... The output terminal (S2, S12, S22) corresponds to a notification unit that notifies the reception unit of the lower sheet feeding unit 50 of permission of power feeding.

  Then, when the receiving unit (S1, S11, S21) accepts the power supply permission, the unit-side power control unit 51 starts the power feeding unit (T1, T11, T21) to supply power, and the supplied voltages (VB1, VB2, VB3). ) Exceeds a predetermined threshold value, it can be said to function as a control unit that notifies the notification unit (S2, S12, S22) of permission of power supply. The threshold value referred to here is, for example, the level of voltages (VB1, VB2, VB3) to the extent necessary to turn on the transistors (Q2, Q12, Q22). Further, the MOSFETs (QF1, QF11, QF21) start power supply from the power supply units (T1, T11, T21) to the motor 53 side in response to reception of power supply permission by the reception units (S1, S11, S21).

  FIG. 3 illustrates the results from the configuration of FIG. FIG. 3A shows a change in voltage with respect to time. The voltage (for example, 42V) output from the distribution circuit 13 to the distribution line L0 and the voltages VB1, VB2, output from the unit-side power control units 51A, 51B, and 51C, respectively. VB3 is shown. 3B, 3C, 3D, and 3E all show changes in current with respect to time. FIG. 3B shows the inrush current IB1 that flows when the MOSFET QF1 of the unit-side power control unit 51A is turned on, and FIG. 3C shows the unit side. FIG. 3D shows an inrush current IB3 that flows when the MOSFET QF11 of the power supply control unit 51B is turned on, and FIG. 3D shows an inrush current IB3 that flows when the MOSFET QF21 of the unit side power supply control unit 51C is turned on. FIG. 3E shows a change in the current I42 that the distribution circuit 13 flows to the distribution line L0. Such an inrush current is generated when, for example, a plurality of paper feeding units 50 are mounted on the main body 11 and then the main body 11 is turned on, or the main body 11 is turned on. This occurs when a plurality of paper feed units 50 are connected at one time (the paper feed unit 50 is connected in a state where the power distribution circuit 13 is distributing power from the distribution line L0. This is also referred to as hot-line insertion).

  As can be seen from the description of FIG. 2 and FIG. 3, according to the present embodiment, the inrush current (IB2) in a certain unit-side power control unit 51 (for example, the unit-side power control unit 51B) is the unit-side power control. After the inrush current (IB1) is generated in the upper unit side power control unit 51 (unit side power control unit 51A) of the unit 51, the upper unit side power control unit 51 (unit side power control unit 51A) outputs It occurs only when the switch (QF11) is turned on when the voltage (VB1) exceeds a predetermined value. Therefore, the generation timing of the inrush current generated in each of the paper feeding units 50 (unit-side power control unit 51) is off. Therefore, the peak value of the current I42 flowing through the power distribution circuit 13 of the main body 11 is not an excessive value obtained by summing the inrush currents of the plurality of paper feeding units 50, and is always less than a certain value (one unit-side power control). (The peak value of the inrush current generated in the portion 51) is suppressed to a value that is suppressed, and the burden on the main body portion 11 is reduced.

  Further, according to the present embodiment, the paper feed units 50 other than the uppermost paper feed unit 50A having the switch drive delay unit 60A and the switch drive unit 61A have completely the same configuration. Therefore, only the uppermost paper feed unit 50A having the switch drive delay unit 60A and the switch drive unit 61A and the same number of paper feed units 50 having the same configuration as desired by the lower users are mounted on the main body 11. The effect as described in FIG. 3 is produced. That is, the generation timing of each inrush current can be surely shifted without performing complicated design and operation such as setting different time constants for each option unit as in the above-mentioned document 1.

  Further, in the timing generation circuit of Document 1, the difference between the response speed that should be originally and the actual response speed varies for each timing generation circuit due to deterioration of the capacitor with time, change in environmental temperature, and the like. Therefore, in order to ensure a difference in the response speed of each timing generation circuit, it is necessary to provide a margin (difference in response speed between timing generation circuits) at the design stage that can absorb the variation of each timing generation circuit. As a result, it takes a long time to activate a plurality of option units. However, in this embodiment, the conduction of the switch of the lower option unit is controlled by the power supply permission (notification signal) generated in response to the increase in voltage generated by the conduction of the switch of the upper option unit. Regardless of deterioration of the capacitor or the like, it is certain that the conduction timing of the switch between the optional units is shifted. Therefore, the time required for starting up the plurality of option units as in the above-mentioned document 1 is not prolonged.

  As can be seen from FIG. 2, according to the configuration of the current limiting unit (62A, 62B, 62C), all paths between the input terminals (T1, T11, T21) and the switches (MOSFETs QF1, QF11, QF21). Is provided with resistance. A switching element such as a MOSFET has a so-called parasitic capacitance. In particular, when the sheet feeding unit 50 is hot-inserted into the main body 11, a kind of inrush current called a spike wave or the like instantaneously flows into such a parasitic capacitance, which may cause a malfunction. . In this embodiment, since resistors are provided in all paths between the input terminals (T1, T11, T21) and the switches (MOSFETs QF1, QF11, QF21), the inrush current flowing to the parasitic capacitance is surely limited. Can do.

  The present invention is not limited to the above-described first embodiment, and can be implemented in various modes without departing from the gist thereof. For example, embodiments described later can be employed. A configuration combining the embodiments also falls within the disclosure scope of the present invention. In each of the following embodiments, points different from the first embodiment will be basically described.

3. Second Embodiment FIG. 4 illustrates a connection mode between the power distribution circuit 13 and each unit-side power control unit 51 according to the second embodiment. 4, when compared with FIG. 2 (first embodiment), the switch drive delay unit 60A and the switch drive unit 61A are arranged not in the unit-side power control unit 51A of the uppermost paper feed unit 50A but in the power distribution circuit 13. It differs in the point provided in. Note that the switch drive delay unit 60A in FIG. 2 and the switch drive delay unit 60A in FIG. 4 are slightly different in the positional relationship between the capacitor C0 and the resistor R03, but their functions as circuits may be considered the same.

  In FIG. 4, the output terminal T0 from the power distribution circuit 13 is connected to the distribution line L0 that outputs the voltage of 42V, while the output terminal S0 from the power distribution circuit 13 is connected to the notification line L01. The notification line L01 is a signal line connected between the resistor R0 and the resistor R01 in the switch driving unit 61A in the power distribution circuit 13. In the unit-side power control unit 51A, the input terminal S1 is directly connected to the gate of the MOSFET QF1. In the power distribution circuit 13, the cathode of the Zener diode Z0 of the switch drive delay unit 60A and the resistor R0 of the switch drive unit 61A are connected to the distribution line L0 that outputs the voltage of 42V. Therefore, the configuration shown in FIG. 4 functions in the same manner as the configuration shown in FIG. According to the second embodiment, all the sheet feeding units 50 including the uppermost sheet feeding unit 50A have the same configuration. Therefore, the user can obtain the effects described with reference to FIG. 3 simply by mounting the desired number of paper feed units 50 having the same configuration on the main body 11.

4). Third Embodiment FIG. 5 illustrates a connection mode between the power distribution circuit 13 and each unit-side power control unit 51 according to the third embodiment. FIG. 5 shows that when compared with FIG. 4 (second embodiment), each unit-side power control unit 51 (51A, 51B, 51C) has connection detection lines (L6, L16, L26) and connection detection lines (L6, L6). L16, L26) are different in that they have an output terminal (U1, U11, U21) at the tip, and that the power distribution circuit 13 has an input terminal U0 at the tip of the connection detection line L02 and the connection detection line L02. The connection detection lines (L6, L16, L26) are branched from the feeder lines (L1, L11, L21).

  In FIG. 5, in the distribution circuit 13, the switch drive delay unit 60 </ b> A is not connected to the distribution line L <b> 0 that outputs the voltage of 42 V, but is connected to the connection detection line L <b> 02. When the power distribution circuit 13 is connected to the unit-side power control unit 51A of the uppermost sheet feeding unit 50A, the input terminal U0 and the output terminal U1 of the unit-side power control unit 51A are connected. That is, a voltage is applied to the cathode of the Zener diode Z0 of the switch drive delay unit 60A via the feeder line L1, the connection detection line L6, the output terminal U1, the input terminal U0, and the connection detection line L02. According to such a configuration, the switch drive delay unit 60A and the switch drive unit 61A in the power distribution circuit 13 do not operate unless the power distribution circuit 13 is connected to the uppermost unit-side power control unit 51A.

  Therefore, when the configuration of FIG. 5 is compared with the configuration of FIG. That is, according to the configuration of FIG. 5, even when a plurality of paper feed units 50 connected in series are hot-inserted into the main body 11, the switch drive delay unit in the power distribution circuit 13 is inserted after the hot-line insertion. 60A and the switch drive unit 61A start operation, and the MOSFET QF1 of the unit-side power control unit 51A is switched from the off state to the on state. Therefore, it is possible to avoid a situation where the voltage VB1 suddenly rises in the unit-side power supply control unit 51A almost simultaneously with the insertion of the hot line, and after the hot line is inserted, the MOSFET QF1 is switched from the off state to the on state with a certain delay. As illustrated in FIG. 5, the voltage VB1 can be gradually increased. Further, according to the third embodiment, all the sheet feeding units 50 including the uppermost sheet feeding unit 50A have the same configuration. Therefore, the user can obtain the effects described with reference to FIG. 3 simply by mounting the desired number of paper feed units 50 having the same configuration on the main body 11.

5. Fourth Embodiment FIG. 6 illustrates a connection mode between the power distribution circuit 13 and each unit-side power control unit 51 according to the fourth embodiment. FIG. 6 does not include the switch drive delay unit 60A and the switch drive unit 61A when compared with FIG. 4 (second embodiment). In addition, the terminal S0 from the power distribution circuit 13 is merely connected to the ground terminal via the signal line L03 and the resistor R04 in the power distribution circuit 13. According to such a configuration, the MOSFET QF1 is switched from the off state to the on state due to a potential difference between the gate and the source (potential difference between the input terminal T1 and the input terminal S1). It is not assumed that the user performs hot-line insertion as described above, and the voltage VB1 in the uppermost unit-side power supply control unit 51A rises with respect to the start timing of the 42V supply by the distribution line L0. Is not required to be delayed (at least, the rising edge of the voltage VB2 is delayed from the voltage VB1 and the rising edge of the voltage VB3 is delayed from the voltage VB2). It can be adopted. According to the fourth embodiment, the configuration of the main body 11 (the power distribution circuit 13) can be simplified and downsized. Further, all the sheet feeding units 50 including the uppermost sheet feeding unit 50A have the same configuration.

6). Fifth Embodiment FIG. 7 illustrates a connection mode between the power distribution circuit 13 and each unit-side power control unit 51 according to the fifth embodiment. 7, when compared with FIG. 2 (first embodiment), the unit-side power control unit 70 is connected in parallel with the unit-side power control unit 51B to the lower side of the unit-side power control unit 51A. It is different in point. In FIG. 7, illustration of the unit side power supply control part 51C connected to the lower order of the unit side power supply control part 51B is omitted. The unit-side power control unit 70 is a power control circuit included in an option unit (referred to as a second option unit) that can be arbitrarily added by the user to the sheet feeding unit 50A. The second option unit is a device for extending the function of the connection destination paper feed unit, and is connected to a connector such as a USB (Universal Serial Bus) port of the connection destination paper feed unit. No other option unit is connected to the subsequent stage of the second option unit.

  In FIG. 7, the distribution line L3 of the unit-side power control unit 51A is branched into an output terminal T2 and an output terminal T3. In addition, the notification line L5 of the unit-side power control unit 51A is branched into an output terminal S2 and an output terminal S3. When the second option unit (not shown) is added to the sheet feeding unit 50A, the input terminal T13 provided in the unit side power supply control unit 70 is connected to the output terminal T3, and the input terminal S13 provided in the unit side power supply control unit 70 is output from the output terminal S3. Connect to each.

  The unit-side power control unit 70 has a function equivalent to the above-described switch drive delay unit and switch drive unit, and a function of connecting to an optional unit in the subsequent stage, as compared with the unit side power control units 51A, 51B, and 51C. There is no simple configuration. That is, in the unit-side power supply control unit 70, the input terminal T13 is connected to the power supply line L31, and the power supply line L31 has the same configuration as the current limiting units (62A, 62B, 62C) described so far. Via the resistors R31, R32, R33, R34 and the current limiting unit 70A including the PNP type bipolar transistor Q31, the gate and the source of the MOSFET QF31 as a switch are connected. The drain of the MOSFET QF31 is connected to the output signal line L32. In the unit-side power control unit 70, the output signal line L32 is connected to an operation unit (such as a motor) included in the second option unit. One end of the electrolytic capacitor C31 is connected to the output signal line L32, and the other end of the electrolytic capacitor C31 is connected to the ground terminal. In the unit-side power control unit 70, the input terminal S13 is connected to the gate of the MOSFET QF31.

  The MOSFET QF31 is switched from the off state to the on state due to a potential difference between the gate and the source (potential difference between the input terminal T13 and the input terminal S13). When the MOSFET QF31 is turned on, a current (inrush current IB21) flows from the input terminal T13 through the resistor R32 and the MOSFET QF31 to the output signal line L32, and a voltage VB21 is generated in the output signal line L32. Charge is stored in the electrolytic capacitor C31 by the inrush current IB21, and the inrush current IB21 disappears when the electrolytic capacitor C31 is fully charged. Thereafter, the voltage VB21 is stably applied to the operation unit of the second option unit connected to the output signal line L32.

  According to the fifth embodiment, the unit-side power control unit 51A (the switch drive delay unit 63A and the switch drive unit 64A) of the paper feed unit 50A is the same as the unit-side power control unit 51B of the lower paper feed unit 50B. It can be said that it is a circuit that controls the drive timing of the switch (MOSFET QF 11) and also has a circuit that controls the drive timing of the switch (MOSFET QF 31) of the unit side power supply control unit 70 of the second option unit. In the fifth embodiment, the resistor R8 is not provided in the switch drive unit 64A of the unit-side power control unit 51A. Instead, the resistor R35 is provided between the power supply line L31 and the gate of the MOSFET QF31 in the unit-side power control unit 70. The resistor R19 may be provided between the power supply line L11 and the gate of the MOSFET QF11 in the unit-side power control unit 51B.

  The resistors R35 and R19 each have a function (voltage division by a ratio with the resistor R7) that the resistor R8 has, but here, the values of the resistors R35 and R19 are made different. With this configuration, in the relationship between the unit-side power supply control unit 51B and the unit-side power supply control unit 70 in which the control units included in the host option unit that generates the input notification signal are shared, the respective switches (MOSFETs QF11, QF31) As a result, the generation timing of the inrush currents IB2 and IB21 can be shifted. Further, according to the fifth embodiment, the unitization of the unit-side power control unit 70 in the second option unit can be reduced in size by the common use. Of course, also in 5th Embodiment, the structure described in 2nd, 3rd, 4th embodiment is applicable about the structure of the power distribution circuit 13 or the unit side power supply control part 51. FIG.

7). Other Embodiments “Connections” between elements shown in the figures merely indicate electrical connections between the elements. Therefore, as long as electrical connection between the elements is possible, another configuration (not shown) may be interposed between the elements, or physical connection (wired connection) may be cut off. In addition, the power supply permission to the lower sheet feeding unit 50 as described above is not an aspect in which a signal (notification signal) is generated, but conversely, the signal that has been generated is interrupted (or the signal level is lowered). Any mode may be used as long as the switch of the lower sheet feeding unit 50 is turned on as a result.
When the optional unit is grasped as the paper feeding unit 50 as described above, the present invention can be applied to any product in which the paper feeding unit 50 can be added. That is, a product to which the present invention is applied may be a product such as a printer that requires paper feeding and does not correspond to a facsimile machine or a multifunction peripheral.

  Moreover, the main-body part 11 can be called a electric power feeding apparatus at the point which supplies electricity in order to drive each option unit. Such a system including the power supply device and the option unit may be realized as an independent product such as a facsimile machine, a multifunction machine, a printer, or the like, and is constructed across a plurality of products and apparatuses. It may be.

  Further, the option unit is not limited to the paper feeding unit. In other words, the relationship between the power supply device and the option unit proposed by the present invention is based on the side (master) that controls the system for power supply and communication constructed in a certain scene, and the side that is connected to the system and controlled Widely applied in relation to (slave). For example, assuming a plurality of batteries (batteries) mounted on an electric vehicle, an in-vehicle controller that controls the operation of the battery corresponds to the power supply apparatus proposed by the present invention, and each battery controlled by the controller is This corresponds to the optional unit proposed by the present invention. Alternatively, assuming a PC and an additional device that is arbitrarily added by the user, the PC corresponds to the power supply device proposed by the present invention, and the additional device corresponds to the option unit proposed by the present invention. To do.

From such a wide viewpoint that does not stop with a product equipped with a paper feeding unit, this embodiment is an optional unit connected to a power feeding device, and electricity is fed from the power feeding device or a higher-order option unit. A power supply unit, a power distribution unit that distributes electricity to the lower option unit, an operation unit that operates with electricity supplied from the power supply unit, and a notification unit that notifies power reception permission to the reception unit of the lower option unit A receiving unit that receives power supply permission from the notification unit of the power supply device or a higher-order option unit, and when the receiving unit receives the power supply permission, the power supply unit starts power supply, and the voltage to be supplied is a predetermined threshold. It can be said that the structure provided with the control part which notifies the said power supply permission to the said notification part when it exceeds a value is disclosed.
Furthermore, the present embodiment is an option unit control system including a power feeding device and an option unit connected to the power feeding device, wherein the power feeding device distributes electricity to the option unit having the highest connection. 1 power distribution unit (output terminal T0) and a first notification unit (output terminal S0) for notifying the highest-order option unit of permission of power supply. The option unit is electrically connected to the power supply device or a higher-order option unit. A power supply unit (input terminals T1, T11, T21) to which power is supplied, a second power distribution unit (output terminals T2, T12, T22) for distributing electricity to the lower option unit, and electricity supplied from the power supply unit. An operation unit that performs an operation, and a second notification unit (output terminals S2, S12, 22), a receiving unit (input terminals S1, S11, S21) that accepts power feeding permission of the power feeding device or a higher-order option unit, and when the receiving unit accepts the power feeding permission, the power feeding unit starts power feeding, It can be said that a configuration is disclosed that includes a control unit that causes the second notification unit to notify the power supply permission when the voltage to be exceeded exceeds a predetermined threshold.

  Also, some or all of the wiring between the power supply device and the option unit or between the option units may be replaced with wireless. The type of radio is arbitrary, but for example, the voltage supply may be replaced by electromagnetic induction wireless power feeding, and the notification signal may also be made wireless by using light that generates a light amount corresponding to the voltage.

DESCRIPTION OF SYMBOLS 10 ... Fax machine (multifunction machine), 11 ... Main part, 12 ... Power supply circuit, 13 ... Power distribution circuit, 14 ... AC plug, 20 ... Facsimile unit, 30 ... Scanner unit, 40 ... Printing unit, 50, 50A, 50B, 50C: Paper feeding unit, 51, 51A, 51B, 51C: Unit-side power control unit, 52 ... Motor drive unit, 53 ... Motor, 57 ... Roller, 62A, 62B, 62C ... Current limiting unit, 63A, 63B, 63C ... Switch drive delay unit, 64A, 64B, 64C ... switch drive unit, 70 ... unit side power supply control unit, 70A ... current limiting unit, M ... paper, Q1, Q2, Q11, Q12, Q21, Q22, Q31 ... transistor, QF1 , QF11, QF21, QF31 ... MOSFET, S1, S11, S21, S13, T1, T11, T2 , T13 ... input terminal, S2, S12, S22, T2, T12, T22 ... output terminal

Claims (6)

A main body including a scanner unit that reads an original and generates image data, a facsimile unit that can transmit and receive image data using a facsimile standard, and a printing unit that prints an image based on the image data on a supplied paper And
A facsimile apparatus comprising: a paper feeding unit for supplying the paper;
The paper feeding unit is
One or more units are mounted with the side closer to the printing unit as the upper level,
A power feeding unit to which electricity is fed from the main body or the upper sheet feeding unit;
A power distribution unit that distributes electricity to the lower paper feed unit;
A motor that operates with electricity supplied from the power supply unit;
A notification unit for notifying the reception unit of the lower-level sheet feeding unit of power supply permission;
A reception unit that receives power supply permission from the notification unit of the main body unit or the upper sheet feeding unit;
An output unit that feeds electricity supplied from the power supply unit to the main body unit when mounted on the uppermost position and connected to the main body unit;
When the acceptance unit accepts the power supply permission, the power supply unit starts power supply to the motor side, and when the voltage supplied to the motor side exceeds a predetermined threshold, the notification unit is notified of the power supply permission. A control unit for causing
The accumulated paper or the paper supplied from the lower paper feeding unit is supplied to the upper paper feeding unit or the printing unit by the power generated by the motor,
The facsimile apparatus according to claim 1, wherein the uppermost sheet feeding unit feeds power from the output unit to the main body unit to notify the main body unit of the power supply permission. An optional unit connected to the power supply device,
The power supply unit that is supplied with electricity from the power supply device or the upper option unit, with the side closer to the power supply device as the upper level,
A power distribution unit that distributes electricity to the lower option unit;
An operation unit that operates with electricity supplied from the power supply unit;
A notification unit for notifying the reception unit of the lower order option unit of power supply permission;
A reception unit that receives power supply permission from the notification unit of the power supply device or the upper option unit;
An output unit that feeds electricity fed from the power feeding unit to the power feeding device when mounted on the uppermost position and connected to the power feeding device;
When the reception unit accepts the power supply permission, the power supply unit starts power supply to the operation unit side, and when the voltage supplied to the operation unit side exceeds a predetermined threshold value, the power supply permission to the notification unit A control unit for notifying
An option unit, wherein when mounted at the uppermost position, the power supply apparatus is notified of the power supply permission by supplying power from the output unit to the power supply apparatus. A main body including a scanner unit that reads an original and generates image data, a facsimile unit that can transmit and receive image data using a facsimile standard, and a printing unit that prints an image based on the image data on a supplied paper And
A facsimile apparatus comprising: a paper feeding unit for supplying the paper;
The paper feeding unit is
One or more units are mounted with the side closer to the printing unit as the upper level,
A power feeding unit to which electricity is fed from the main body or the upper sheet feeding unit;
A power distribution unit that distributes electricity to the lower paper feed unit;
A motor that operates with electricity supplied from the power supply unit;
A notification unit for notifying the reception unit of the lower-level sheet feeding unit of power supply permission;
A reception unit that receives power supply permission from the notification unit of the main body unit or the upper sheet feeding unit;
When the acceptance unit accepts the power supply permission, the power supply unit starts power supply to the motor side, and when the voltage supplied to the motor side exceeds a predetermined threshold, the notification unit is notified of the power supply permission. A control unit for causing
The control unit includes a MOSFET as a switch interposed between the power feeding unit and the motor, a capacitor having one end connected between the MOSFET and the motor and the other end connected to a ground terminal, A bipolar device in which a cathode is connected between the MOSFET and the one end of the capacitor, a base is connected to the anode side of the Zener diode, a collector is connected to the notification unit, and an emitter is connected to a ground terminal A transistor, and
The reception unit is connected to the gate of the MOSFET,
The MOSFET switches from the non-conducting state to the conducting state according to the difference between the voltage at the power feeding unit and the voltage at which the receiving unit accepts the power feeding permission, thereby passing between the source and drain of the MOSFET from the power feeding unit. Then, electric charge is stored in the capacitor by the current input to the motor side, and the Zener diode breaks down in response to an increase in voltage supplied to the motor side, and after the breakdown, the bipolar transistor is turned off. By switching from the conductive state to the conductive state, a signal as the power supply permission is generated on the collector side,
The facsimile apparatus characterized in that the paper supply unit supplies the accumulated paper or the paper supplied from the lower paper supply unit to the upper paper supply unit or the printing unit by the power generated by the motor. . An optional unit connected to the power supply device,
The power supply unit that is supplied with electricity from the power supply device or the upper option unit, with the side closer to the power supply device as the upper level,
A power distribution unit that distributes electricity to the lower option unit;
An operation unit that operates with electricity supplied from the power supply unit;
A notification unit for notifying the reception unit of the lower order option unit of power supply permission;
A reception unit that receives power supply permission from the notification unit of the power supply device or the upper option unit;
When the reception unit accepts the power supply permission, the power supply unit starts power supply to the operation unit side, and when the voltage supplied to the operation unit side exceeds a predetermined threshold value, the power supply permission to the notification unit A control unit for notifying
The control unit includes a MOSFET as a switch interposed between the power supply unit and the operation unit, and a capacitor having one end connected between the MOSFET and the operation unit and the other end connected to a ground terminal. A Zener diode having a cathode connected between the MOSFET and the one end of the capacitor; a base connected to the anode side of the Zener diode; a collector connected to the notification unit; and an emitter connected to a ground terminal. Bipolar transistors, and
The reception unit is connected to the gate of the MOSFET,
The MOSFET switches from the non-conducting state to the conducting state according to the difference between the voltage at the power feeding unit and the voltage at which the receiving unit accepts the power feeding permission, thereby passing between the source and drain of the MOSFET from the power feeding unit. Then, electric charge is stored in the capacitor by the current input to the operating unit side, and the Zener diode breaks down in response to an increase in voltage supplied to the operating unit side, and after the breakdown, the bipolar transistor The optional unit is characterized in that a signal for permitting power feeding is generated on the collector side by switching from a non-conductive state to a conductive state. A main body including a scanner unit that reads an original and generates image data, a facsimile unit that can transmit and receive image data using a facsimile standard, and a printing unit that prints an image based on the image data on a supplied paper And
A facsimile apparatus comprising: a paper feeding unit for supplying the paper;
The paper feeding unit is
One or more units are mounted with the side closer to the printing unit as the upper level,
A power feeding unit to which electricity is fed from the main body or the upper sheet feeding unit;
A power distribution unit that distributes electricity to the lower paper feed unit;
A motor that operates with electricity supplied from the power supply unit;
A notification unit for notifying the reception unit of the lower-level sheet feeding unit of power supply permission;
A reception unit that receives power supply permission from the notification unit of the main body unit or the upper sheet feeding unit;
A control unit that causes the power supply unit to start power supply when the reception unit receives the power supply permission, and that notifies the power supply permission to the notification unit when a voltage to be supplied exceeds a predetermined threshold;
The control unit includes a MOSFET as a switch interposed between the power feeding unit and the motor, and has a resistance provided in all paths between the power feeding unit and the MOSFET, and is based on the reception unit. in response to the receiving of the feed permitted to conduct the MOSFET, notifies the power supply permission to the notification unit according to the voltage fed to the motor side by the MOSFET is conductive exceeds the threshold Let
The facsimile apparatus characterized in that the paper supply unit supplies the accumulated paper or the paper supplied from the lower paper supply unit to the upper paper supply unit or the printing unit by the power generated by the motor. . An optional unit connected to the power supply device,
The power supply unit that is supplied with electricity from the power supply device or the upper option unit, with the side closer to the power supply device as the upper level,
A power distribution unit that distributes electricity to the lower option unit;
An operation unit that operates with electricity supplied from the power supply unit;
A notification unit for notifying the reception unit of the lower order option unit of power supply permission;
A reception unit that receives power supply permission from the notification unit of the power supply device or the upper option unit;
A control unit that causes the power supply unit to start power supply when the reception unit receives the power supply permission, and that notifies the power supply permission to the notification unit when a voltage to be supplied exceeds a predetermined threshold;
The control unit includes a MOSFET as a switch interposed between the power supply unit and the operation unit, and includes a resistor in all paths between the power supply unit and the MOSFET, and the reception unit the power supply permits the notification unit according to to conduct the MOSFET in response to the receiving of the power supply permission, the voltage fed to the operation portion side by the MOSFET is conductive exceeds the threshold An optional unit characterized by

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