JP4666611B2 - Charging system and power storage server - Google Patents

Description

  The present invention relates to a technique for supplying electric power to a fixing unit provided in an image forming apparatus for the purpose of fixing toner onto a recording sheet with heat.

Conventionally, in an image forming apparatus such as a copying machine, an auxiliary power source (a capacitor, a secondary battery, or the like) has been provided in order to raise a fixing unit that fixes toner onto a recording sheet by heat to a fixing possible temperature in a short time. Have been proposed. As such an image forming apparatus, a large current is caused to flow to the fixing heater using both a commercial power source (external power source) and an auxiliary power source when shifting to a printable state at the initial startup of the image forming apparatus. A device that shortens the rise time has been proposed (see Patent Document 1 below).
Japanese Patent Laid-Open No. 10-282821

  However, when a mechanism for supplying power to the fixing unit by adding an auxiliary power source as described above is employed, the auxiliary power source must be provided in the image forming apparatus, which increases the size of the image forming apparatus. The manufacturing cost is increased accordingly. Further, in such an image forming apparatus, since the auxiliary power supply is not always fully charged immediately after introduction, it is possible to supply power to the fixing unit by the auxiliary power immediately after introduction. Not exclusively.

  The present invention has been made in view of the above problems, and can raise the fixing unit to a fixable temperature in a short time without increasing the size of the image forming apparatus and without increasing the manufacturing cost. An object of the present invention is to enable the fixing unit to be raised to a fixable temperature in a short time immediately after the introduction of the image forming apparatus.

The invention according to claim 1 is a charging system comprising a plurality of image forming apparatus, and a power storage server supplies power to the plurality of the image forming apparatus,
The image forming apparatus includes: a first fixing heater that heats a fixing unit that fixes toner onto a recording sheet with power supplied from the power storage server; and a first fixing heater that switches whether to drive the first fixing heater. A driving unit; a second fixing heater that heats the fixing unit with power from a commercial power source; a second fixing heater driving unit that switches whether to drive the second fixing heater; and power for the power storage server. Request signal transmitting means for transmitting a power supply request signal for requesting supply of
The power storage server includes a plurality of auxiliary power sources that charge power to be supplied to the fixing unit of the image forming apparatus, and a charge control unit that is provided for each auxiliary power source and controls charging of the auxiliary power source using commercial power. When the power supply request signal is received from any of the plurality of image forming apparatuses, an auxiliary power supply that supplies power to the image forming apparatus is selected from the plurality of auxiliary power supplies, and the power of the selected auxiliary power supply is selected. The control unit that selects the image forming apparatus that has transmitted the power supply request signal as the supply destination, and the image forming unit that has selected the auxiliary power source selected by the control unit as the power supply destination of the auxiliary power source. And power supply control means connected to the apparatus .

The invention according to claim 2 is the charging system according to claim 1, wherein the control unit of the power storage server receives the power supply request signal from the image forming apparatus, and the plurality of auxiliary power supplies. An auxiliary power source that is not selected as an auxiliary power source that supplies power to the image forming apparatus is selected as an auxiliary power source that supplies power to the image forming apparatus that has transmitted the power supply request signal .

According to these configurations, the electric storage server, the auxiliary power supply is charged with the power of the commercial power supply, the power supply destination to become the image forming apparatus of the auxiliary power supply is selected by the power supply destination selecting unit, the image forming apparatus , The first and second fixing heater driving means switch the driving and non-driving of both the first fixing heater using the power of the auxiliary power source and the second fixing heater using the power of the commercial power source to fix the fixing unit. Is heated.

In these configurations, in the power storage server, the power supply destination selection unit selects the auxiliary power source from the plurality of auxiliary power sources, and power is supplied from the selected auxiliary power source to the image forming apparatus. Yes.

The invention according to claim 3, a charging system according to claim 1 or請 Motomeko 2, the control unit of the electric storage server, among the plurality of auxiliary power, the power to the image forming apparatus wherein as charging is performed for the auxiliary power source is not selected as the supplying auxiliary power supply, in which the charging control unit Ru to perform the charge control.

  In this configuration, the control unit of the power storage server performs charging of the auxiliary power source that is not selected as the auxiliary power source that supplies power to the image forming apparatus by the power supply destination selecting unit from among the plurality of auxiliary power sources. Since the charging control means performs charging control, charging of each auxiliary power source is performed at a timing that does not hinder power supply to the image forming apparatus.

The invention according to claim 4 is the charging system according to any one of claims 1 to 3, wherein the auxiliary power source of the power storage server is:
A lithium ion battery charged with power from the commercial power source;
An electric double layer capacitor connected to the lithium ion battery;
Provided between the lithium ion battery and the electric double layer capacitor, and switches between a connection for charging the electric double layer capacitor with power from the lithium ion battery and a connection for charging the lithium ion battery with power from the commercial power source. With switch
Is provided.

In this configuration , the electric double layer capacitor can be kept in a fully charged state with the electric power from the lithium ion battery, so that the electric double layer capacitor voltage is reduced by the discharge of electric charge and the electric power supplied to the image forming apparatus is reduced. There is no inconvenience of lowering. In addition, the lithium ion battery functions as a charge for the electric double layer capacitor and does not function as a power supply for supplying power to the image forming apparatus. Therefore, the lithium ion battery does not discharge with a large current. Since it does not repeat, the lifetime of a lithium ion battery can be kept long.

The invention according to claim 5 is a power storage server for supplying power to each of a plurality of image forming apparatuses,
A plurality of auxiliary power sources for charging power supplied to the fixing unit of the image forming apparatus;
Charging control means provided for each auxiliary power supply for controlling charging by the power of the commercial power supply to the auxiliary power supply;
When a power supply request signal for requesting power supply is received from any of the plurality of image forming apparatuses, an auxiliary power supply that supplies power to the image forming apparatus is selected from the plurality of auxiliary power supplies, and the selected auxiliary power supply is selected. Control means for selecting the image forming apparatus that has transmitted the power supply request signal as a power supply destination of a power supply ;
Power supply control means for connecting the auxiliary power source selected by the control means to the image forming apparatus selected as a power supply destination of the auxiliary power source .

According to the first and second aspects of the present invention, the fixing unit can be heated with electric power larger than that of the commercial power supply without providing the image forming apparatus with a power storage mechanism such as an auxiliary power supply. Therefore, it is not necessary to increase the size of the conventional image forming apparatus in order to heat the fixing unit with power larger than that of the commercial power source. In addition, since the power storage mechanism need not be provided, the manufacturing cost of the image forming apparatus does not increase. In addition, since the power storage server charges the auxiliary power supply regardless of whether the image forming apparatus is in operation or not, even if the image forming apparatus is newly installed, the auxiliary power source of the power storage server is in a charged state. The power supply from the auxiliary power source to the fixing unit of the image forming apparatus can be started immediately after the introduction, and the fixing unit can be brought into a fixable state in a short time . Et al is, since the auxiliary power source selected from a plurality of auxiliary power of the electric storage server can supply power to the image forming apparatus, one auxiliary power supply, even if supplying power to an image forming apparatus, Electric power can be supplied from another auxiliary power source to another image forming apparatus. As a result, it is possible to smoothly supply power to a plurality of image forming apparatuses from one power storage server.

  According to the third aspect of the present invention, it is possible to charge the other auxiliary power supply while supplying power to the image forming apparatus from one auxiliary power supply, which hinders power supply to the image forming apparatus. In parallel with this, the auxiliary power source that is not supplying power to the image forming apparatus can be charged smoothly.

According to the fourth aspect of the present invention , the electric double layer capacitor can be kept in a fully charged state with the electric power from the lithium ion battery. There is no problem that the power supplied to the forming apparatus is reduced. In addition, the lithium ion battery functions as a charge for the electric double layer capacitor and does not function as a power supply for supplying power to the image forming apparatus. Therefore, the lithium ion battery does not discharge with a large current. Since it does not repeat, the lifetime of a lithium ion battery can be kept long.

  According to the fifth aspect of the present invention, it is possible to supply power larger than the power of the commercial power supply to the fixing unit of the image forming apparatus that does not include the power storage mechanism.

  Embodiments according to the present invention will be described below with reference to the drawings. FIG. 1 is a block diagram showing a charging system according to the present invention. The charging system 1 according to the present invention includes a power storage server 2 and one or more multifunction peripherals 31, 32, 33, etc. The multi-function machines 31, 32, 33,... Are connected so as to be able to receive power supply from the power storage server 2.

  The power storage server 2 supplies auxiliary power to the multifunction devices 31, 32, 33,... For starting up the fixing unit provided in the multifunction devices 31, 32, 33, etc. in a short time. The multifunction devices 31, 32, 33,... Have a printer, a copying machine, a facsimile machine, or a combination of these functions. The multifunction peripherals 31, 32, 33,... Receive power supplied from the power storage server 2 and drive the fixing heater of the fixing unit. In the present embodiment, the image forming apparatus according to the present invention is described as the above-described multifunction peripheral. However, the image forming apparatus according to the present invention is not limited to only the multifunction peripheral.

  A power supply request signal or a power supply stop signal is sent from the multi-function devices 31, 32, 33,. The power storage server 2 controls charging of the internal charging mechanism based on the power supply request signal or the power supply stop signal. The power storage server 2 and the multifunction peripherals 31, 32, 33, ... are supplied with electric power from an external power source (a so-called commercial power source, an AC (alternating current) power source by an electric power company) 5.

  Next, a circuit of the power supply mechanism of the power storage server 2 will be described. FIG. 2 is a diagram illustrating a circuit image of the power supply mechanism of the power storage server 2. The power storage server 2 includes three charging mechanisms 21, 22, and 23 and a power supply control unit (power supply destination selection means, power supply selection means) 25. In addition, the number of the charging mechanisms shown in this embodiment should just be one or more, and it is not the meaning which limits the number of the charging mechanisms with which the electrical storage server 2 is provided to three.

  The charging mechanisms 21, 22, and 23 are each connected to the external power supply 5 via the diode 20. The diode 20 rectifies AC current into DC current. As a result, a DC current flows through the charging mechanisms 21, 22, and 23. The charging mechanisms 21, 22, and 23 are connected to the power supply control unit 25. The power supply control unit 25 includes a first switch that selects a charging mechanism that supplies power to any one of the multi-function machines 31, 32, 33,. And a second switch for selecting a multifunction device that receives power supply from any of the multifunction devices 31, 32, 33,... (Not shown). By the switching control of the first and second switches by the power supply control unit 25, the power from one charging mechanism among the charging mechanisms 21, 22, 23 is supplied to one multifunction device. Yes.

  The charging mechanisms 21, 22, and 23 will be described. Since the charging mechanisms 21, 22, and 23 have the same configuration, the charging mechanism 21 will be described as an example. The charging mechanism 21 includes a battery charging control circuit (charging control means) 211, a lithium ion battery (auxiliary power source) 212, a switching regulator 213, an electric double layer capacitor (auxiliary power source) 214, and a relay switch 215.

  The battery charge control circuit 211 is a switch that switches whether to charge the lithium ion battery 212 by switching whether to supply power from the external power supply 5 to the lithium ion battery 212. The connection of the relay switch 215 to the side for charging the lithium ion battery 212 is switched, and the power from the external power supply 5 is supplied to the lithium ion battery 212 by the battery charge control circuit 211, so that the lithium ion battery 212 is supplied. Is charged.

  The lithium ion battery 212 is a rechargeable power source that supplies electric power to the electric double layer capacitor 214 in order to charge the electric double layer capacitor 214. The lithium ion battery 212 is characterized by a small voltage drop until the end of discharge. The charging time of the lithium ion battery 212 is, for example, 10 minutes.

  The switching regulator 213 is a power supply stabilization device that smoothes the voltage input from the lithium ion battery 212 and outputs a stable DC voltage to the electric double layer capacitor 214.

  The electric double layer capacitor 214 functions as an auxiliary power source for driving a first fixing heater (described later) provided in the multifunction machine 31 or the like. The electric double layer capacitor 214 can be charged and discharged with a large current. Although the electric double layer capacitor 214 has a relatively long charge / discharge life (for example, on the order of hundreds of thousands of times), the electric power (voltage) rapidly decreases when electric charge is released. The charging time of the electric double layer capacitor 214 is, for example, several tens of seconds.

  The relay switch 215 connects the lithium ion battery 212 with a circuit so that (1) the electric double layer capacitor 214 is charged with power discharged from the lithium ion battery 212, or (2) the external power supply 5 is a power supply source. Is a switch for switching the circuit to be connected to charge the lithium ion battery 212 (described above).

That is, in the charging mechanism 21, the current from the diode 20 is supplied to the lithium ion battery 212 via the battery charge control circuit 211, and the relay switch 215 is provided between the battery charge control circuit 211 and the lithium ion battery 212. Therefore, the relay switch 215 can be used to connect (1) power to the electric double layer capacitor 214 from the lithium ion battery 212 and charge the electric double layer capacitor 214 with the electric power of the lithium ion battery 212. (2) The connection is switched between connecting the lithium ion battery 212 to the battery charge control circuit 211 side and charging the lithium ion battery 212 with the electric power from the external power source 5.

  The electric double layer capacitor 214 is connected to the switching regulator 213 and is charged with electric power from the lithium ion battery 212. The electric double layer capacitor 214 is also connected to the power supply control unit 25, and supplies the electric power of the electric double layer capacitor 214 to any of the multi-function devices 31, 32, and 33 via the power supply control unit 25. It is like that.

  According to such a configuration, the electric double layer capacitor 214 can be kept in a fully charged state with the electric power from the lithium ion battery 212. Therefore, the voltage of the electric double layer capacitor 214 is lowered by the discharge of the electric charge and combined. There is no problem that the power supplied to the machine decreases. Further, the lithium ion battery 212 functions to charge the electric double layer capacitor 214 and does not function as a power supply for supplying power to the multifunction machine. Therefore, the life of the lithium ion battery 212 can be kept long.

  Next, the circuits of the multifunction machines 31, 32, 33. The multi-function devices 31, 32, 33,... Have the same configuration, and therefore, the multi-function device 31 will be described below as an example. FIG. 3 is a diagram showing a circuit image of the power supply mechanism of the multi-function machine 31, and particularly shows a power supply mechanism portion to the fixing heater. The multi-function device 31 includes a fixing heater 300 including a first fixing heater 311 and a second fixing heater 312, a first fixing heater driving circuit (first fixing heater driving means) 313, and a second fixing heater driving circuit (second fixing heater). Fixing heater driving means) 314.

  The first fixing heater 311 and the second fixing heater 312 are heaters for heating the fixing roller. In the present embodiment, the first fixing heater 311 and the second fixing heater 312 are halogen heaters. The first fixing heater 311 is, for example, a 1300 to 1800 W DC (direct current) heater, and the second fixing heater 312 is, for example, a 1200 W AC (alternating current) heater. The first fixing heater 311 uses a large power consumption in order to heat rapidly by flowing a large current. The first fixing heater 311 and the second fixing heater 312 are installed adjacent to each other.

  The first fixing heater driving circuit 313 controls whether or not the first fixing heater 311 is driven by electric power from the electric double layer capacitor 214 provided in any of the charging mechanisms 21, 22, and 23 of the power storage server 2. It is. That is, the first fixing heater driving circuit 313 functions as a switch for switching whether or not the first fixing heater 311 is heated by the electric power from the electric double layer capacitor 214. When the switch is turned on, the first fixing heater 311 is driven, and when the switch is turned off, the first fixing heater 311 is stopped.

  The second fixing heater driving circuit 314 functions as a switch for switching whether to drive the second fixing heater 312 using the external power source 5 as a power supply source, that is, whether to heat the second fixing heater 312. When the switch is turned on, the second fixing heater 312 is driven, and when the switch is turned off, the second fixing heater 312 is stopped.

  Next, control of each unit of the power storage server 2 and the multifunction machine 31 will be described. FIG. 4 is a block diagram showing the internal configuration of the multi-function machine 31, and particularly shows a power supply mechanism portion to the fixing heater. FIG. 5 is a block diagram illustrating an internal configuration of the power storage server 2, and is a functional configuration diagram centering on a power supply mechanism portion particularly to the fixing unit of the multifunction peripheral. In FIG. 5, the thick line indicates the power supply direction, and the thin line indicates the instruction signal (control signal). FIG. 6 shows each state type of the multi-function device 31 (plug-in state, initial startup state, print state, ready state, sleep state, and rapid startup state) and an opportunity to transition from each state to another state. This is state transition information indicating the type of event.

  The multifunction device 31 will be described. The multi-function device 31 includes a power control circuit 316, a main switch 317, a recording unit 318, an instruction receiving unit 319, a timer 320, a fixing roller temperature sensor 321, a control unit 310, a first fixing heater 311, a first fixing heater driving circuit 313, a first one. 2 fixing heaters 312 and a second fixing heater driving circuit 314 are provided.

  The power supply control circuit 316 controls whether or not the power from the external power supply 5 (FIG. 1) is supplied to each part of the apparatus in response to turning on or off of the main switch 317 that is a main power switch for starting the multifunction machine 31. Is.

  The recording unit 318 records a toner image on recording paper, and the multifunction device 31 operates in response to a print instruction when a copy function, a printer function, or a facsimile reception function is executed, for example. The recording unit 318 includes a scanner unit 3181, an image forming unit 3182, and a fixing unit 3183.

  A scanner unit 3181 includes a document irradiation lamp, a CCD, and the like, and reads an image described on a document to be copied. The image forming unit 3182 includes, for example, a photosensitive drum, a charging device, an exposure device, a transfer device, and the like, and is a mechanism that forms an image on recording paper by an electrophotographic method.

  The fixing unit 3183 includes a fixing roller (not shown) including a heat roller and a pressure roller, and nips the recording paper on which the toner image is transferred by the photosensitive drum with the heat roller and the pressure roller, and the toner is generated by heat and pressure. The image is fixed on the recording paper.

  The instruction receiving unit 319 receives various operation execution instructions from the user or the like for the multi-function device 31 and receives, for example, execution instructions for a copy function, a printer function, and a facsimile reception function. In the instruction receiving unit 319, a copy function execution instruction is input to the multi-function peripheral 31 by the user from the operation panel (not shown) of the multi-function peripheral 31. The printer function execution instruction is transmitted to the multifunction device 31 from, for example, a PC (personal computer) connected to the multifunction device 31 via a network or the like. The facsimile reception execution instruction is transmitted to the multifunction device 31 from a facsimile transmission device connected to the multifunction device 31 through a public line or the like. The print instruction is an execution instruction for an operation for recording an image on recording paper by the operation of the recording unit 318, and is included in the execution instruction for a copy function, a printer function, a facsimile reception function, and the like.

  The timer 320 measures the elapsed time and the current time from when the instruction is received from the state determination unit 3103. The fixing roller temperature sensor 321 measures the temperature of the fixing roller and outputs it to the fixing roller temperature control unit 3102.

  The control unit 310 controls the overall operation of the multifunction machine 31, and includes a CPU (Central Processing Unit) that executes a program, a ROM (Read Only Memory) that stores the program, and a temporary storage area when the program is executed. It is comprised from RAM (random access memory) etc. which are used as. The control unit (control unit) 310 includes an operation control unit 3101, a fixing roller temperature control unit 3102, a state determination unit 3103, and a switch control unit 3104.

  The operation control unit 3101 controls operation of each unit of the multi-function device 31 and controls the operation of the recording unit 318 and the like based on execution instructions such as a copy function and a print function received by the instruction receiving unit 319.

  The state determination unit 3103 determines whether the current state of the MFP 31 is in an initial startup state, a print state, a ready state, a sleep state, a plug-in state, or a rapid startup state. is there. Based on the on / off state of the main switch 317 sent from the power supply control circuit 316 or the absence of a print instruction from the instruction receiving unit 319 for a predetermined time, the state determination unit 3103 is Determine if it is in a state.

  The initial startup state is a predetermined first temperature range in which the temperature of the fixing roller can be fixed (for example, around 180 ° C., for example, from the time when power is supplied to the multi-function device 31 (after the main switch 317 is turned on). This is the state up to).

  The print state is a state during the printing operation of the multi-function device 31 (a state from when printing (including copying) is completed until it is completed). In the printing state, the temperature of the fixing roller is kept within the first temperature range.

  The ready state is a state where the input of the print instruction is waited and the fixing roller can be immediately raised to the first temperature range if there is a print instruction. In this ready state, the temperature of the fixing roller is set to a second temperature range (for example, around 90 ° C.) that is lower than the first temperature range.

  The sleep state is a state in which the first fixing heater 311 and the second fixing heater 312 are turned off for power saving, and when a print instruction is not input for a certain period of time, the sleep state is shifted to the sleep state. It has become.

  The plug-in state is a state where the power plug is inserted into the outlet of the external power source 5 but the main switch 317 is turned off.

  The rapid start-up state refers to a state in which, when a print instruction is received in the sleep state, the temperature of the fixing roller rises to the first temperature range in which the fixing roller can be fixed.

  The state determination unit 3103 stores the state transition information shown in FIG. 6 in advance, and determines the current state (transition source state) and the state (transition destination state) that makes the next transition from the generated event. Based on the on / off state of the main switch 317 sent from the power supply control circuit 316 or the absence of a print instruction from the instruction receiving unit 319 for a predetermined time, the state determination unit 3103 is Determine if it is in a state. The state determination unit 3103 sends information indicating the determined current state and the next transition state to the switch control unit 3104.

  The fixing roller temperature control unit 3102 is based on the temperature value detected by the fixing roller temperature sensor 321 so that the temperature of the fixing roller falls within the first temperature range in the printing state. The second fixing heater driving circuit 314 is driven and controlled, and the first fixing heater 311 and the second fixing heater 312 are turned on and off. The fixing roller temperature control unit 3102 controls on / off of the second fixing heater 312 so that the temperature of the fixing roller is within a predetermined second temperature range in the ready state. Each control by the fixing roller temperature control unit 3102 is performed via the switch control unit 3104.

  The switch control unit 3104 includes a first fixing heater driving circuit 313 and a second fixing heater driving circuit 313 for each current state of the multifunction machine 31 determined by the state determination unit 3103 or based on an instruction from the fixing roller temperature control unit 3102. The switching of the fixing heater driving circuit 314 is controlled. In addition, the switch control unit 3104 transmits a power supply request signal or a power supply stop signal to the control unit 26 of the power storage server 2.

  The power storage server 2 will be described. The power storage server 2 includes a control unit 26. This control unit 26 is based on the power supply request signal or the power supply stop signal transmitted from the switch control unit 3104 of the multi-function device 31, 32, 33..., And controls the battery charging control. Whether to control the operation of the circuit 211 to charge the lithium ion battery 212 and the electric double layer capacitor 214 in the charging mechanisms 21, 22, 23, and whether to supply the electric power of the electric double layer capacitor 214 to the multifunction device Switch between. In the following description, the power supply control by the battery charge control circuit 211 may be indicated as ON when power is supplied, and OFF when power is not supplied.

  For example, when a power supply request signal is sent from the switch control unit 3104 of a certain multifunction device to the control unit 26, the control unit 26 selects another multifunction device from the charging mechanisms 21, 22, and 23. A charging mechanism that is not used for power supply to the printer is detected, the first switch of the power supply control unit 25 is switched, and the detected charging mechanism is connected to the multifunction device side. When a power supply stop request is sent from the switch control unit 3104 of a certain multifunction device to the control unit 26, the control unit 26 switches the second switch of the power supply control unit 25 and charges until then. The multifunction device connected to the mechanism side is disconnected from the charging mechanism side, and power supply from the charging mechanism that has been supplying power is stopped.

  Further, when the charging mechanism is not supplying power to the multifunction device, the control unit 26 connects the relay switch 215 of the charging mechanism to the battery charging control circuit 211 side and turns on the battery charging control circuit 211. As a result, the lithium ion battery 212 is controlled to be charged by the power of the external power source 5. In addition, the control unit 26 connects the relay switch 215 to the electric double layer capacitor 214 side, turns off the battery charge control circuit 211, and turns off the electric double layer capacitor 214 from the electric double layer capacitor 214. Control is performed so that the electric power of the electric double layer capacitor 214 is supplied to any of the multifunction machines 31, 32, 33.

  FIG. 7 is a diagram illustrating the states of the first fixing heater driving circuit 313 and the second fixing heater driving circuit 314 in each state of the multifunction machine 31 and whether or not to transmit a power supply request signal to the power storage server 2.

  The switching control of the first fixing heater control circuit 313 and the second fixing heater driving circuit 314 corresponding to each state of the multi-function device 31 and the transmission control of either the power supply request signal or the power supply stop signal to the power storage server 2 This is performed by the control unit 3104. The switch controller 3104 itself determines whether the first fixing heater control circuit 313 and the second fixing heater drive circuit 314 corresponding to each state of the multifunction machine 31 and whether to transmit a power supply request signal to the power storage server 2. It may be stored, or may be stored in a storage unit (not shown) and read by the switch control unit 3104 as necessary.

  In the initial start-up state and the rapid start-up state, the first fixing heater control circuit 313 is turned on, the first fixing heater control circuit 313 drives the first fixing heater 311, and the second fixing heater drive circuit 314. Is also turned on, and the second fixing heater 312 is driven by the second fixing heater driving circuit 314. In this case, as described above, the first fixing heater 311 is driven by the electric power supplied from the power storage server 2, and the second fixing heater 312 is driven by the electric power supplied from the external power supply 5. In addition, a power supply request signal is transmitted to the power storage server 2.

  In the ready state, the first fixing heater control circuit 313 is turned off, the first fixing heater 311 is not driven, the second fixing heater driving circuit 314 is turned on, and the second fixing heater 312 is driven. It is made a state. In addition, a power supply stop signal is transmitted to the power storage server 2.

  In the sleep state and the plug-in state, the first fixing heater control circuit 313 is turned off, the first fixing heater 311 is not driven, the second fixing heater drive circuit 314 is also turned off, and the second fixing heater 312 is It is in a non-driven state. A power supply stop signal is transmitted to the power storage server 2.

  In the print state, the first fixing heater control circuit 313 switches between driving and non-driving of the first fixing heater 311 based on the temperature value of the fixing roller input from the fixing roller temperature sensor 321 to the switch control unit 3104, and fixing. The temperature of the roller is maintained in the first temperature range. The second fixing heater driving circuit 314 is turned on, and the second fixing heater 312 is driven. In addition, a power supply request signal is transmitted to the power storage server 2.

  Next, power supply control by the power storage server 2 in the charging system 1 and processing at the time of fixing heater drive control in the multifunction machine 31 and the like will be described. 8 to 10 are flowcharts showing power supply control by the power storage server 2 and processing at the time of fixing heater drive control in the multifunction machine 31 and the like in the charging system 1. In the following, processing by any one of the multi-function machines 31, 32, 33... Will be described using the multi-function machine 31 as an example.

  When the multifunction device 31 has its power plug attached to an outlet and a signal indicating the state is sent from the power control circuit 316 to the state determination unit 3103, the state determination unit 3103 indicates that the multifunction device 31 is in the plug-in state. The switch controller 3104 determines that the first fixing heater control circuit 313 does not drive the first fixing heater 311 and the second fixing heater drive circuit 314 does not drive the second fixing heater 312 (S1). . Furthermore, the switch control unit 3104 transmits a power supply stop signal to the power storage server 2 (S2).

  In the power storage server 2, when the control unit 26 receives the power supply stop signal from the multifunction device 31 (SS1), the control unit 26 switches the second switch of the power supply control unit 25 so that the multifunction device 31 is connected to the charging mechanism. The state is disconnected from the 21, 22, 23 side (hereinafter simply referred to as the charging mechanism side). Then, the control unit 26 switches the relay switch 215 to connect the lithium ion battery 212 to the battery charge control circuit 211 side, turns on the battery charge control circuit 211, and uses the power from the external power supply 5 to recharge the lithium ion battery 212. Is charged (SS2).

  When the power control circuit 316 detects that the main switch 317 (main power switch) of the multi-function peripheral 31 is turned on (YES in S3), the power control circuit 316 indicates that the main switch 317 is turned on. Is sent to the state determination unit 3103. With this, the state determination unit 3103 determines that the state of the multifunction device 31 is the initial startup state, and sends a signal indicating the device state to the switch control unit 3104. The switch control unit 3104 transmits a power supply request signal to the power storage server 2 (S4). Subsequently, the switch controller 3104 turns on the first fixing heater control circuit 313 to drive the first fixing heater 311 and also turns on the second fixing heater drive circuit 314 to drive the second fixing heater 312 (S5).

  In the power storage server 2, when the control unit 26 receives the power supply request signal from the multi-function device 31 (SS3), the control unit 26 detects a charging mechanism that is not supplying power to other multi-function devices at this time. (SS4), the first switch of the power supply control unit 25 is switched to connect the detected charging mechanism to the multifunction device side, and the second switch is switched to connect the multifunction device 31 to the charging mechanism side ( SS5). Then, the control unit 26 switches the relay switch 215 to the side that discharges the lithium ion battery 212 (the side that charges the electric double layer capacitor 214), and turns off the battery charging control circuit 211 (SS6). As a result, the detected electric power of the electric double layer capacitor 214 of the charging mechanism is supplied to the multifunction peripheral that has transmitted the power supply request instruction.

  When the switching control is performed as described above, the first fixing heater 311 is driven by the power supply from the power storage server 2 in addition to the second fixing heater 312. This state is continued until it is detected by the fixing roller temperature control unit 3102 and the switch control unit 3104 that the temperature of the fixing roller obtained from the fixing roller temperature sensor 321 has reached the first temperature range described above ( S6).

  When the fixing roller temperature sensor 321 detects that the temperature of the fixing roller has reached the first temperature range (YES in S6), the state determination unit 3103 indicates that a print instruction has been received from the instruction receiving unit 319. It is determined whether a signal is input (S7). When a signal indicating that a print instruction has been received is input from the instruction reception unit 319 (YES in S7), the state determination unit 3103 determines that the state of the multi-function device 31 is the print state, and indicates this apparatus state. A signal is sent to the switch control unit 3104. The switch control unit 3104 transmits a power supply request signal to the power storage server 2 (S8). In this case, the power storage server 2 performs the processes of SS3 to SS6 described above.

  In the multi-function device 31, the switch control unit 3104 maintains a state in which the second fixing heater driving circuit 314 drives the second fixing heater 312, while the first fixing heater control circuit 313 includes a fixing roller temperature sensor 321. Based on the temperature value sent from, the driving / non-driving of the first fixing heater 311 is switched in a timely manner so that the temperature of the fixing roller maintains the first temperature range (S9). At the time of printing, depending on the state of paper passing to the fixing roller, the heating of the fixing roller may be taken away by the recording paper only by the heating of the recording paper by the second fixing heater 312, so that the temperature of the fixing roller is lowered. This is because the temperature of the fixing roller is kept constant while avoiding the temperature drop. The operation control unit 3101 causes the recording unit 318 to perform a recording operation (S10).

  When printing is completed by the recording operation of the recording unit 318 (YES in S11), the state determination unit 3103 determines that the state of the multi-function device 31 is in the ready state, and sends a signal indicating the device state to the switch control unit. 3104. The switch control unit 3104 turns on the second fixing heater driving circuit 314 and keeps the second fixing heater 312 in the driving state, but turns off the first fixing heater control circuit 313 and puts the first fixing heater 311 in the driving stop state. (S12). Further, the switch control unit 3104 transmits a power supply stop signal to the power storage server 2 (S13). In this case, the power storage server 2 performs a series of processes described in the explanations of SS1 and SS2.

  Even when a signal indicating that a print instruction has been received from the instruction receiving unit 319 in S7 is not input to the state determining unit 3103 (NO in S7), the state determining unit 3103 sets the state of the multifunction device 31 to the ready state. The apparatus status is sent to the switch control unit 3104, and the processes of S12 and S13 are performed.

  If the state determination unit 3103 determines that the state of the multi-function device 31 is the ready state, the state determination unit 3103 performs the processing of S12 and S13 and causes the timer 320 to start measuring the time elapsed from the time point determined to be the ready state (S14). ). When the instruction receiving unit 319 receives a print instruction during the elapsed time measurement by the timer 320 (YES in S15), the operation control unit 3101 returns the process to S8.

  If the print instruction is not received by the instruction receiving unit 319 (NO in S15) and the timer 320 measures that a predetermined time (for example, 1 minute) has elapsed (YES in S16), the state determining unit 3103 Then, it is determined that the state of the multifunction device 31 is in the sleep state, and a signal indicating the device state is sent to the switch control unit 3104. The switch control unit 3104 turns off the first fixing heater control circuit 313 to place the first fixing heater 311 in a driving stop state, turns off the second fixing heater drive circuit 314, and puts the second fixing heater 312 in a stopped state (S17). . Thus, by setting both the first fixing heater 311 and the second fixing heater 312 to the stop state, the printer waits for a further print instruction with reduced power consumption. Further, the switch control unit 3104 transmits a power supply stop signal to the power storage server 2 (S18). In this case, the power storage server 2 performs a series of processes described in the explanations of SS1 and SS2.

  In the multifunction device 31, when the print instruction is received by the instruction reception unit 319 and the signal indicating that the print instruction is received is input from the instruction reception unit 319 to the state determination unit 3103 in the sleep state ( In step S19, YES, the state determination unit 3103 determines that the state of the multi-function device 31 is a rapid startup state, and sends a signal indicating the device state to the switch control unit 3104. In this rapid start-up state, the switch control unit 3104 transmits a power supply request signal to the power storage server 2 (S20), turns on the first fixing heater control circuit 313, and drives the first fixing heater 311. The second fixing heater driving circuit 314 is also turned on to drive the second fixing heater 312 (S21). In this case, the power storage server 2 performs the processes of SS3 to SS6 described above.

  Thereafter, when the fixing roller temperature sensor 321 detects that the temperature of the fixing roller has reached the first temperature range (YES in S22), the process returns to S8, and the processes of S8 to S22 are repeated. It is. Note that if it is detected that the main switch 317 is turned off at any point in time from S4 to S22, the process returns to S1.

  In addition, this invention is not limited to the thing of the said embodiment, The aspect described below can be employ | adopted further. In FIG. 2 described above, the electric double layer capacitor 214 is configured to be charged with the electric power of the lithium ion battery 212, but the present invention is not limited to this configuration. A configuration including only the double layer capacitor 214 or the lithium ion battery 212 may be adopted.

  Further, in the above-described embodiment, a DC current flows through the charging mechanisms 21, 22, 23 and the first fixing heater 311, and an AC current flows through the second fixing heater 312. The current flowing through each fixing heater is not limited to using AC or DC.

  In each of the above embodiments, the electric double layer capacitor 214 and the lithium ion battery 212 are used as the auxiliary power source. However, the electric double layer capacitor 214 or the lithium ion battery 212 is merely an example, and other types are used. It doesn't matter.

  The configuration and processing shown in FIGS. 1 to 10 are merely one embodiment of the present invention, and the configuration and processing of the present invention are not limited to these.

It is a block diagram which shows the charging system which concerns on this invention. It is a figure which shows the circuit image of the electric power supply mechanism of an electrical storage server. FIG. 2 is a diagram showing a circuit image of a power supply mechanism of a multifunction peripheral, and particularly shows a power supply mechanism portion for a fixing heater. 2 is a block diagram showing an internal configuration of the multifunction machine, and particularly shows a power supply mechanism portion to the fixing heater. FIG. FIG. 2 is a block diagram showing an internal configuration of a power storage server, and is a functional configuration diagram centered on a power supply mechanism portion for a fixing unit of a multifunction machine. Each status type of the MFP (plug-in status, initial startup status, print status, ready status, sleep status, and rapid startup status) and the event type that triggers transition from each status to another status State transition information to be shown. FIG. 6 is a diagram illustrating states of a first fixing heater driving circuit and a second fixing heater driving circuit in each state of the multifunction peripheral and whether or not a power supply request signal is transmitted to the power storage server. 6 is a flowchart illustrating power supply control by a power storage server and processing at the time of fixing heater driving control in a multifunction peripheral in a charging system. 6 is a flowchart illustrating power supply control by a power storage server and processing at the time of fixing heater driving control in a multifunction peripheral in a charging system. 6 is a flowchart illustrating power supply control by a power storage server and processing at the time of fixing heater driving control in a multifunction peripheral in a charging system.

DESCRIPTION OF SYMBOLS 1 Charging system 2 Power storage server 5 External power supply 20 Diode 21, 22, 23 Charging mechanism 211 Battery charging control circuit 212 Lithium ion battery 213 Switching regulator 214 Electric double layer capacitor 215 Relay switch 25 Electric supply control unit 26 Control unit 31, 32, 33 MFP 310 Control Unit 3101 Operation Control Unit 3102 Fixing Roller Temperature Control Unit 3103 State Determination Unit 3104 Switch Control Unit 300 Fixing Heater 311 First Fixing Heater 312 Second Fixing Heater 313 First Fixing Heater Control Circuit 314 Second Fixing Heater Drive Circuit 316 Power control circuit 317 Main switch 3183 Fixing part

Claims (5)

A charging system comprising a plurality of image forming apparatuses and a power storage server that supplies power to each of the plurality of image forming apparatuses,
The image forming apparatus includes: a first fixing heater that heats a fixing unit that fixes toner onto a recording sheet with power supplied from the power storage server; and a first fixing heater that switches whether to drive the first fixing heater. A driving unit; a second fixing heater that heats the fixing unit with power from a commercial power source; a second fixing heater driving unit that switches whether to drive the second fixing heater; and power for the power storage server. Request signal transmitting means for transmitting a power supply request signal for requesting supply of
The power storage server includes a plurality of auxiliary power sources that charge power to be supplied to the fixing unit of the image forming apparatus, and a charge control unit that is provided for each auxiliary power source and controls charging of the auxiliary power source using commercial power. When the power supply request signal is received from any of the plurality of image forming apparatuses, an auxiliary power supply that supplies power to the image forming apparatus is selected from the plurality of auxiliary power supplies, and the power of the selected auxiliary power supply is selected. The control unit that selects the image forming apparatus that has transmitted the power supply request signal as the supply destination, and the image forming unit that has selected the auxiliary power source selected by the control unit as the power supply destination of the auxiliary power source. A charging system having power supply control means connected to the apparatus . The control means of the power storage server , when receiving the power supply request signal from the image forming apparatus, an auxiliary power that is not selected as an auxiliary power supply for supplying power to the image forming apparatus from the plurality of auxiliary power supplies The charging system according to claim 1, wherein a power source is selected as an auxiliary power source that supplies power to the image forming apparatus that has transmitted the power supply request signal . The control means of the power storage server provides the charge control means with the charge control means so that the auxiliary power supply that is not selected as an auxiliary power supply that supplies power to the image forming apparatus among the plurality of auxiliary power supplies is charged. the charging system of claim 1 or請 Motomeko 2 Ru to perform the charge control. The auxiliary power supply of the power storage server is
  A lithium ion battery charged with power from the commercial power source;
  An electric double layer capacitor connected to the lithium ion battery;
Provided between the lithium ion battery and the electric double layer capacitor, and switches between a connection for charging the electric double layer capacitor with power from the lithium ion battery and a connection for charging the lithium ion battery with power from the commercial power source. With switch
The charging system according to any one of claims 1 to 3, further comprising: A power storage server that supplies power to each of a plurality of image forming apparatuses,
A plurality of auxiliary power sources for charging power supplied to the fixing unit of the image forming apparatus;
Charging control means provided for each auxiliary power supply for controlling charging by the power of the commercial power supply to the auxiliary power supply;
When a power supply request signal for requesting power supply is received from any of the plurality of image forming apparatuses, an auxiliary power supply that supplies power to the image forming apparatus is selected from the plurality of auxiliary power supplies, and the selected auxiliary power supply is selected. Control means for selecting the image forming apparatus that has transmitted the power supply request signal as a power supply destination of a power supply ;
An electricity storage server comprising: power supply control means for connecting the auxiliary power source selected by the control means to the image forming apparatus selected as a power supply destination of the auxiliary power source .

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