JP4965815B2 - Process cartridge, image forming apparatus, and power management apparatus - Google Patents

Description

  The present invention relates to a process cartridge, an image forming apparatus, and a power management apparatus. More specifically, the present invention relates to a process cartridge that stores data necessary for power management of the image forming apparatus, and detachably mounts the process cartridge to reduce power consumption. The present invention relates to an image forming apparatus that performs image processing and a power management apparatus that optimizes process cartridge data.

  In an electrophotographic image forming apparatus such as a facsimile machine, a copying machine, and a printer, an image forming process voltage for placing a developer on a photoreceptor, detection of the remaining amount of the developer, and fixing the developer on a transfer sheet Output various analog signals such as the temperature of the fixing unit to the control circuit from each part of the image forming unit, fixing unit, etc., and optimize each state by the control circuit to improve the quality of the formed image I am trying.

  In recent years, there is a strong demand for energy saving in image forming apparatuses, and there is a demand for reducing power consumption of the image forming apparatus in a standby state other than during an image forming operation. Therefore, in recent image forming apparatuses, in order to reduce the power consumption in the standby state, in the standby state, power is supplied only to the minimum necessary units, and power is supplied to the units that are used only during the image forming operation. Is stopped, the power consumption of the entire system as the image forming apparatus is reduced. The image forming apparatus provided with the energy saving mode includes a plurality of energy saving modes having different power consumption values as the energy saving mode.

  Then, the applicant first calculates and displays the power consumption in each energy saving mode in the image forming apparatus having a plurality of energy saving modes, so that the user can grasp the power consumption. A forming apparatus has been proposed (see Patent Document 1).

JP 2002-225395 A

  However, in the conventional technology, the user can understand the power consumption in each energy saving mode. However, in order to improve the energy saving more efficiently, the energy saving corresponding to the recent process cartridge is improved. There was a need to improve it.

  That is, in the above prior art, it is possible to know the amount of power consumption in the energy saving mode at each stage, but it is possible to optimize the transition time between each power mode, that is, the state of the power mode to further increase the power consumption. In order to reduce power consumption, improvements were necessary.

  In particular, in recent years, an image forming apparatus for forming an image by mounting a process cartridge in which a photosensitive member and a developing unit are integrated in a cartridge has appeared. In addition to forming an image using such a process cartridge, an energy saving mode, etc. There is a demand for a technique that can be applied appropriately when reducing the power consumption by optimizing the state of each power mode when the power modes are executed to reduce the power consumption.

  Accordingly, the present invention includes a storage unit that stores power management data necessary for reducing power consumption of an image forming apparatus that forms an image by transitioning between a plurality of power modes, and a process for reducing power consumption. The cartridge, the image forming apparatus that appropriately reduces power consumption based on the power management data of the process cartridge, and the power management data of the process cartridge are optimized according to the usage form, and further reduce the power consumption of the image forming apparatus It aims at providing the power management device which aims at.

In order to achieve the above object, the first means of the present invention comprises a plurality of power modes having different power consumptions, and is detachable from an image forming apparatus that transitions between the power modes in a set transition time. in the process cartridge mounted, at least the respective power mode, the power consumption per unit time in the respective power modes, the number of transitions of the each power mode, the time maintenance of the power modes, consumption in the respective power modes power mode optimal based average power calculated from electric energy, and stores the power control data consisting of setting the transition time between the respective power modes, to the power management data by the control means provided in said image forming apparatus optimum the optimal setting of the transition time de between the power mode to reduce power consumption in the image forming apparatus determined by performing the process Motor is characterized in that the storage means is provided which is read and written by the control of the control means which receives a predetermined instruction from the operation unit provided in the image forming apparatus.

In the image forming apparatus in which the second means forms an image using a process cartridge and includes a plurality of power modes having different power consumptions, and transitions between the power modes at a set transition time. the calculation at least said respective power mode, the power consumption per the unit time at each power mode, the number of transitions of the each power mode, the time maintenance of the power mode, the power consumption in the respective power modes the average power consumption was, and consumption in the image forming apparatus is control means provided in the image forming apparatus is determined by performing a power mode optimization process based on the power control data consisting of setting the transition time between the respective power modes operation provided the data of the optimum setting transition time between optimal the respective power modes to reduce power to the image forming apparatus Storage means for storing is provided by the control of the control means which receives a predetermined instruction from said control means, the data of the optimum set migration time read from the storage means in response to an instruction from the operating unit The power consumption is reduced by controlling the success or failure of the activation accompanying the transition of each power mode related to each unit provided in the image forming apparatus .

The third means includes a plurality of power modes having different power consumptions , and a process that is detachably attached to an image forming apparatus that reduces power consumption by appropriately setting a transition time between the power modes. Attached to the cartridge, at least each power mode, power consumption per unit time in each power mode, number of transitions to each power mode, maintenance time of each power mode, power consumption in each power mode The power management data is read in response to a predetermined instruction from an external operation unit from a storage unit that stores power management data including the average power consumption calculated from the amount and the set transition time between the power modes. Based on the management data, the optimum transition time data between the power modes is determined to reduce the power consumption of the image forming apparatus. Control means for performing power mode optimization processing and storing data of the optimum setting transition time obtained by the power mode optimization processing in the storage means, wherein the control means is instructed by the external operation unit In response to the data of the optimum setting transition time read from the storage means, the success or failure of the activation associated with the transition of each power mode related to each section provided in the image forming apparatus is controlled to reduce the power consumption. characterized in that it.

According to the process cartridge of the present invention, the storage device stores the power management data necessary for managing the power consumption of the detachably mounted image forming apparatus, and the control unit provided in the image forming apparatus converts the power management data into the power management data. Based on the control instructed by the operation unit, the data of the optimum setting transition time between each power mode optimal for reducing the power consumption in the image forming apparatus determined by performing the power mode optimization processing based on the control is stored. for reading from and writing to a unit, start with the transition of each power mode according to each part provided in the image forming apparatus using the power management data of the control means memorize unit of the image forming apparatus (data of the optimum setting transition time) by controlling the success or failure of, it is possible to optimally reduce power consumption, the time of replacement of the process cartridge, the power management data storage means (at optimum settings migration Data) is optimized in accordance with the use form, that is attached to the image forming apparatus again, it is possible to further appropriately reduce power consumption.

According to the image forming apparatus of the present invention, the control unit provided in the image forming apparatus is provided in the process cartridge to which the image forming apparatus is detachably mounted when transitioning between a plurality of power modes having different power consumptions with a set transition time. imaging data of the optimum transition time between optimal respective power modes to reduce power consumption in the image forming apparatus determined by performing a power mode optimization process based on the stored electric power management data obtained storage means Under the control of the control means receives an instruction operation section provided in the device stores the memorize means, according to each part provided in the image forming apparatus reads the data of the optimum transition time of startup accompanying the transition of each power mode and controls the success, it is possible to optimally reduce power consumption, the time of replacement of the process cartridge, the power management data storage means ( Optimized data suitable set migration time) in accordance with the use form, that is attached again, it is possible to reduce the power consumption even more appropriately.

According to the power management device of the present invention, viewed write control means provided in the power management unit to read by receiving a predetermined instruction to power management data by an external operation unit from the storage unit of the process cartridge, in accordance power control data Based on this, power mode optimization processing is performed to determine the optimal transition time data between each power mode that is optimal for reducing power consumption in the image forming apparatus, and the obtained optimal transition time data is stored in the storage means. At the same time, receiving an instruction from the external operation unit, reading the data of the optimum transition time from the storage unit, and controlling the success or failure of the activation associated with the transition of each power mode of each unit provided in the image forming apparatus, thereby forming an image. with the power consumption when applied can be optimally reduced in the apparatus, the timing of replacement of the process cartridge, the power management data storage means (outermost Data) configuration transition time optimum turn into can isosamples according to the use form.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, since the Example described below is a suitable Example of this invention, various technically preferable restrictions are attached | subjected, However, The scope of the present invention limits this invention especially in the following description. As long as there is no description of the effect, it is not restricted to these aspects.

  1 to 12 are diagrams showing an embodiment of the process cartridge, the image forming apparatus, and the power management apparatus of the present invention. FIG. 1 is an embodiment of the process cartridge, the image forming apparatus, and the power management apparatus of the present invention. 1 is a schematic front view of a color image forming apparatus 1 to which an example is applied.

  In FIG. 1, the color image forming apparatus 1 includes a main body housing 2 in which a paper feeding unit 10, a plotter unit 20, and the like are housed, and a scanner unit 110 is disposed on the upper part of the main body housing 2.

  The scanner unit 110 irradiates a document with reading light, performs main scanning / sub scanning on the document, reads an image of the document, and transfers image data of the read document to the plotter unit 20.

  The paper feed unit 10 includes a first paper feed tray 11, a second paper feed tray 12, paper feed rollers 13 and 14, separation pads 15 and 16, a transport roller 17 and a registration roller 18. 11 and 12 each store a plurality of recording papers P of various paper sizes. The paper supply unit 10 separates the recording paper P in the paper supply trays 11 and 12 one by one by the paper supply rollers 13 and 14 and the separation pads 15 and 16, and sends them to the conveyance roller 17. 18 to transport. The registration roller 18 adjusts the timing of the recording paper P conveyed by the conveyance roller 17 and then conveys it to the plotter unit 20.

  The plotter unit 20 includes a photosensitive belt unit 30, M (magenta), C (cyan), Y (yellow), and K (black) process cartridges 40M, 40C, 40Y, and 40K, an intermediate transfer belt unit 50, and a secondary transfer. The image forming apparatus 1 includes a unit 60, a writing unit 70, a charging unit 80, a fixing unit 90, a paper discharge unit 100, and the like. Is formed.

  The photosensitive belt unit 30 includes rollers 31, 32, and 33, a belt-shaped photosensitive belt 34 that is formed in an annular shape and stretched between the rollers 31 to 33, a photosensitive member cleaning unit 35, a photosensitive member waste toner bottle 36, and the like. The photosensitive belt 34 is rotationally driven in the clockwise direction in FIG. 1 along with the rollers 31 to 33 when at least one of the rollers 31 to 33 is rotationally driven.

  The charging unit 80 is disposed in the vicinity of the roller 32 in the vicinity of the photosensitive belt 34 and uniformly charges the photosensitive belt 34.

  The writing unit 70 sequentially irradiates the photosensitive belt 34 uniformly charged by the charging unit 80 with the laser beam modulated based on the image data of each color from the scanner unit 110 one by one. Each time the belt 34 makes one revolution, an electrostatic latent image of each color is sequentially formed on the photosensitive belt 34.

  As shown in FIG. 2, the process cartridges 40M to 40K are arranged in the order of M (magenta), C (cyan), Y (yellow), and K (black) from the lower side, and each color toner of MCYK. Bottles 41M, 41C, 41Y, and 41K and developing units 42M, 42C, 42Y, and 42K are accommodated in cartridges 43M, 43C, 43Y, and 43K. The process cartridges 40 to 40K supply toner of each color from the toner bottles 41M, 41C, 41Y, and 41K of the respective colors to the corresponding developing units 42M, 42C, 42Y, and 42K, and the developing units 42M, 42C, 42Y, and 42K of the respective colors Sequentially, each time the photosensitive belt 34 makes one turn, the toner of the color with respect to the electrostatic latent image of the color on the photosensitive belt 34 formed by the writing unit 70 based on the image data of each color. The toner image of each color is sequentially formed by supplying the toner.

  The photoreceptor belt 34 is rotated so that the toner image of each color formed on the photoreceptor belt 34 is sequentially transferred to the intermediate transfer belt 51 of the intermediate transfer belt unit 50 at the roller 33 portion every round. The images are superimposed and transferred, and a full-color toner image is transferred and formed on the intermediate transfer belt 51.

  After the transfer, the remaining toner is removed by the photoreceptor cleaning unit 35 and the removed waste toner is stored in the photoreceptor waste toner bottle 36.

  The intermediate transfer belt unit 50 has the intermediate transfer belt 51 laid around a plurality of rollers 52, and is driven to rotate counterclockwise in FIG. 1 by at least one roller 52 being driven to rotate. The intermediate transfer belt unit 50 includes an intermediate transfer belt cleaning unit 53, an intermediate transfer waste toner bottle 54, an intermediate transfer roller 55, and the like. The intermediate transfer roller 55 intermediates toner images of each color on the photosensitive belt 34. A color toner image is formed by sequentially superimposing and transferring on the transfer belt 51.

  The intermediate transfer belt 51 is provided with a secondary transfer unit 60 at a position opposite to the photosensitive belt 34, and the paper feeding unit is interposed between the secondary transfer unit 60 and the intermediate transfer belt 51. The recording paper P is fed out from the ten paper feed trays 11 and 12 and the timing is adjusted by the registration rollers 18.

  The secondary transfer unit 60 transfers the color toner image on the intermediate transfer belt 51 onto the recording paper P that has been conveyed to the intermediate transfer belt 51.

  After the transfer is completed, the remaining toner is removed by the intermediate transfer belt cleaning unit 53 and the removed waste toner is stored in the intermediate transfer waste toner bottle 54.

  The plotter unit 20 conveys the recording paper P onto which the color toner image has been transferred by the secondary transfer unit 60 to the fixing unit 90, and heats and presses the recording paper P while conveying the recording paper P by the fixing unit 90. The toner image on P is fixed on recording paper P.

  The fixing unit 90 conveys the recording paper P that has been fixed to the paper discharge unit 100, and the paper discharge unit 100 discharges the recording paper P that has been fixed onto the paper discharge tray 3.

  As shown in FIG. 2, the process cartridges 40M to 40K are detachably provided with cartridge memories (storage means) 44M to 44K, respectively, and the cartridge memories 44M to 44K are supplied with power. A non-volatile memory is used to retain the stored contents even when there is not.

  The cartridge memories 44M to 44K can perform data processing such as data writing, reading, and erasing by the color image forming apparatus 1, and at least various power modes provided in the color image forming apparatus 1 and in the power mode. Power management data consisting of power consumption per unit time, number of transitions to each power mode, each power mode maintenance time, average power consumption calculated from power consumption in each power mode, and setting transition time between each power mode Remember.

  The color image forming apparatus 1 has a block configuration as shown in FIG. 3, and includes a CPU (Central Processing Unit) 201, a ROM (Read Only Memory) 202, a RAM (Random Access Memory) 203, an operation panel 204, a serial number. Communication module 205, I / O control unit 206, various sensors 207, various motors 208, reading control unit 209, scanner unit 110, writing control unit 210, plotter unit 20, communication control unit 211, network control unit 212, etc. The above-described units are connected by a bus 213.

  The ROM 202 stores a basic program as the color image forming apparatus 1, various programs such as a power reduction processing program and a power mode optimization processing program described later, and various data necessary for executing these various programs. The RAM 203 is used as a work memory for the CPU 201 and stores various data associated with the operation of the CPU 201 and other necessary various data.

  The CPU 201 executes basic processing as the color image forming apparatus 1 by controlling each unit of the color image forming apparatus 1 while using the RAM 203 as a work memory based on a program in the ROM 202, Various processing such as power mode optimization processing is executed.

  The operation panel 204 includes operation keys for performing various operations of the color image forming apparatus 1 and a display such as an LCD (Liquid Crystal Display) for displaying and outputting various information.

  The serial communication module 205 is connected to the cartridge memories 44M to 44K of the process cartridges 40M to 40K in a wired or wireless manner, and reads and writes necessary power management data from the cartridge memories 44M to 44K under the control of the CPU 201. .

  The I / O control unit 206 includes various sensors (for example, a paper sensor that detects the presence or absence of the recording paper P in the paper feeding trays 11 and 12, a paper feeding sensor that detects the conveyance state of the recording paper P, and the registration roller 18. A registration sensor 207 that detects the conveyance of the recording paper P 207 and various motors 208 (for example, a photosensitive belt motor that drives the photosensitive belt 34, a paper feed motor that rotates the paper feed rollers 13 and 14) 208 are connected. Under the control of the CPU 201, signals from the various sensors 207 are taken in and passed to the CPU 201, and the CPU 201 controls the driving of the various motors 208.

  A scanner unit 110 is connected to the reading control unit 209, and the reading control unit 209 controls the operation of the scanner unit 110 under the control of the CPU 201.

  The plotter unit 20 is connected to the write control unit 210, and the operation of the plotter unit 20 is controlled under the control of the write control unit 209.

  A network control unit 212 is connected to the communication control unit 211, and a line such as a public telephone line or a dedicated line is connected to the network control unit 212. The network control unit 212 operates under the control of the CPU 201 and the communication control unit 211 to automatically receive a call from a line and perform automatic call processing to the line. The communication control unit 211 exchanges facsimile control signals with a partner facsimile apparatus connected via a line connected to the network control unit 212, performs data conversion, and executes a facsimile communication procedure. .

  Further, the color image forming apparatus 1 of the present embodiment has a plurality of power modes with different power consumptions as shown in the transition diagram of the power modes in FIG.

  In FIG. 4, the standby mode is a stand-by state of the color image forming apparatus 1 main body, and the plotter output mode is an operating state of the color image forming apparatus 1 such as a copy operation and a plotter operation. In the standby mode, the color image forming apparatus 1 now has a timer value T1 that is a predetermined setting transition time when the preheat key on the operation panel 204 is pressed or when an arbitrary operation is performed from the operation panel 204 in advance. After that, a low power consumption process such as turning off the display or lowering the set temperature of the fixing unit 90 is performed to shift to a preheat mode in which the power consumption is lowered to the preheat state.

  Further, in the preheating mode, the color image forming apparatus 1 has a timer value T2 that is a predetermined setting transition time when a preheating key on the operation panel 204 is pressed or when an arbitrary operation is performed on the operation panel 204 in advance. Later, a transition is made to the low power mode that satisfies the conditions defined in the energy star standard low power mode.

  Further, in the low power mode, the color image forming apparatus 1 has a timer that is a predetermined setting transition time when the power key on the operation panel 204 is pressed or when an arbitrary operation is performed on the operation panel 204 in advance. After the value T3, the process shifts to the fixing OFF / silent mode that satisfies the conditions defined in the energy star standard sleep mode.

  Further, in the fixing OFF / silent mode, the color image forming apparatus 1 has a predetermined setting set as an internal timer by a program in the ROM 202 when the color image forming apparatus 1 has only a copy function. After time t2, which is the transition time, the color image forming apparatus 1 shifts to a stop mode that satisfies the conditions defined in the off mode of the energy star standard, and the color image forming apparatus 1 has a combined function such as a copy, printer, scanner, and FAX. If there is, the program shifts to a sleep mode that satisfies the conditions defined in the off mode of the Energy Star standard after a time t1 that is a predetermined setting shift time set as an internal timer in the program in the ROM 202.

  In the color image forming apparatus 1, the return conditions from the above modes are as follows. That is, when returning from the stop mode, the color image forming apparatus 1 performs operation B shown in FIG. 4 by turning on the power key on the operation panel 204 / detecting the pressure plate (document pressing) opening by the scanner unit 110 / detecting the document set. Transition to standby mode. Further, when the color image forming apparatus 1 returns from the pause mode, the operation B shown in FIG. 4 is performed: ON the power key on the operation panel 204 / Presser plate (document pressing) opening detection / document setting detection by the scanner unit 110. A transition is made to the standby mode, and a transition is made to the fixing OFF / silent mode in response to a release request K2: printer output request / FAX (ringing detection / F network ringing detection / external phone off-hook detection).

  Further, when the color image forming apparatus 1 returns from the fixing OFF / silent mode, the operation A shown in FIG. 4: ON of the power key on the operation panel 204 / detection of key operation other than the power key / pressure plate in the scanner unit 110 ( Document holding) Transition to standby mode by opening detection / document setting detection, release request K1: printer output request / FAX: ringing detection / FAX: F network ringing detection, and standby except that display on operation panel 204 is OFF Transition to night standby mode A / night output mode A, which is equivalent to the mode. The color image forming apparatus 1 is in the sleep mode of the energy star standard from the night standby mode or after a timer value T4 that is a predetermined setting transition time by performing an arbitrary operation on the operation panel 204 in advance. Transition to fixing OFF / silent mode that satisfies the defined conditions.

  Further, when the color image forming apparatus 1 returns from the preheating mode and the low power mode, the operation A: power key ON on the operation panel 204 / key operation detection other than the power key / pressure plate (scanning the original) in the scanner unit 110 Transition to standby mode by open detection / document set detection, release request K1: printer output request / FAX: ringing detection / FAX: F network ringing detection, except that the display on the operation panel 204 is OFF and the preheating LED is ON Transition to night standby mode B / night output mode B, which is equivalent to the standby mode.

  Further, the color image forming apparatus 1 also enters the preheating mode after the timer value T5 which is a set transition time set by performing any operation from the operation panel 204 in advance from the night standby mode B on the operation panel 204. When a key operation other than the power supply is detected, the standby mode is entered, and the night standby mode A is entered when the power key on the operation panel 204 is pressed.

  Further, when the color image forming apparatus 1 is in the standby mode and the power key on the operation panel 204 is pressed, the power key on the operation panel 204 is set to the fixing OFF / silent mode or the plotter output mode. When pressed, the mode changes to night output mode / night standby mode.

  Next, the operation of this embodiment will be described. The color image forming apparatus 1 according to the present embodiment stores at least the power consumption value in each power mode, each power mode, and each power mode in the cartridge memories 44M to 44K together with the management information of the color image forming apparatus 1 main body. Each transition mode is stored based on the set transition time, and each power mode transition process is performed based on the set transition time. The power consumption is further reduced according to the user usage mode.

  That is, as shown in FIG. 4, the color image forming apparatus 1 includes a standby mode, a plotter output mode, a preheating mode, a low power mode, a fixing OFF / silent mode, a stop mode, a pause mode, two night standby modes A, B and two nighttime output modes A and B are provided, and the transition between the power modes is performed according to various operations such as key operation on the operation panel 204, opening of the pressure plate, and document insertion operation. And based on the setting transition time.

  When the color image forming apparatus 1 operates by changing the power modes, the color image forming apparatus 1 measures the operation time (elapsed time) in each power mode, and stores it in each of the cartridge memories 44M to 44K as shown in FIG. In the case where the serial communication module 205 stores and stores the power consumption amount in each power mode and the elapsed time in each power mode is stored as shown in FIG. As shown, the average power consumption value at that time is calculated and stored in the cartridge memories 44M-44K.

{(Ta × 191 + Tb × 125 + Tc × 92 + Td × 48 + Te × 14 + Tf × 6 + Th × 191 + Ti × 191) / 3600 + 780 + 650 + 650} ÷ {Ta + Tb + Tc + Td + Te + Tf + Tg + Th + Ti + Tj + Tk} (1)
That is, in the color image forming apparatus 1, the CPU 201 checks whether there is a change in the power mode as shown in FIG. 6 (step S101). Based on the calculation formula (1) (step S102), the power consumption value for each power mode, the power mode holding time (elapsed time), and the calculation formula (1) are stored in the cartridge memories 44M to 44K of the process cartridges 40M to 40K. The average power consumption value calculated in step S103 is written (step S103).

  Further, in the color image forming apparatus 1, the CPU 201 uses the cartridge memories 44M to 44K in the process cartridges 40M to 40K to which the cartridge memories 44M to 44K are attached and the toner end time (year). Month / day) is stored via the serial communication module 205.

  Then, the CPU 201 calculates the average power consumption during the usage period of the process cartridges 40M to 40K from Tend that is the use start time (year / month / day) and toner end time (year / month / day) of the process cartridges 40M to 40K. The calculation is made based on the formula (2) and is stored in the cartridge memories 44M to 44K.

{(Ta × 191 + Tb × 125 + Tc × 92 + Td × 48 + Te × 14 + Tf × 6 + Th × 191 + Ti × 191) / 3600 + 780 + 650 + 650} ÷ {Tend × 3600} (2)
That is, in the color image forming apparatus 1, the CPU 201 checks whether there is a change in the power mode as shown in FIG. 7 (step S201). Based on the calculation formula (2) (step S202), the power consumption value for each power mode, the power mode holding time, and the average calculated by the calculation formula (2) are stored in the cartridge memories 44M to 44K of the process cartridges 40M to 40K. The power consumption value is written (step S203).

  The color image forming apparatus 1 stores the power management data as described above. In particular, as shown in FIG. 8, the mode holding time determination criterion and the average power consumption value in each power mode are based on the reference value Wx. The recommended setting transition time depending on whether or not is larger is stored. The recommended setting transition time is stored in the cartridge memories 44M to 44K on the process cartridges 40M to 40K or the cartridge memories 44M to 44K at the time of removal from the process cartridges 40M to 40K, and the average power consumption at that time is These values are set for each of cases where the determination criterion Wx is larger and smaller than the criterion Wx stored in advance in the RAM 203 of the color image forming apparatus 1 or the RAM 303 of the analysis apparatus 300 described later.

  In the color image forming apparatus 1, the CPU 201 determines the power management data that is stored in the cartridge memories 44 </ b> M to 44 </ b> K, in particular, the mode setting time determination criterion for each power mode and the recommended setting transition time based on the reference value Wx. The data is read from the cartridge memories 44M to 44K, written to the RAM 203, and transition control of each power mode is performed based on the data stored in the RAM 203.

  The color image forming apparatus 1 performs transition control of each power mode based on the data written in the RAM 203, performs an image forming operation using the process cartridges 40M to 40K, repeatedly performs the image forming operation, When the life of the process cartridges 40M to 40K comes to an end, replacement of the process cartridges 40M to 40K is performed by a user or a service person.

  Then, the process cartridges 40M to 40K removed from the color image forming apparatus 1 are sent to a predetermined service station or the like (hereinafter referred to as a service station) of the color image forming apparatus 1 by the user, or the service person performs the service. An analysis device (power management device) 300 as shown in FIG. 9 is installed in the service station.

  The analysis apparatus 300 executes an optimum power mode analysis process for determining and determining each setting transition time, which is an optimum setting transition time for each power mode, based on the data of the process cartridges 40M to 40K. RAM 303, operation panel 304, serial communication module 305, socket 306, write control unit 307, plotter unit 308, and the like, and main components are connected by a bus 309.

  The ROM 302 executes the optimum power mode analysis processing program and the optimum power mode analysis processing program for judging and determining each setting transition time which is the optimum setting transition time of each power mode based on the data of the process cartridges 40M to 40K. Various data necessary for the storage are stored.

  The CPU 301 executes the optimum power analysis mode processing using the RAM 303 as a work memory based on the optimum power mode analysis processing program in the ROM 302.

  The RAM 303 is used as a work memory of the CPU 301 and stores a mode holding time determination criterion in each power mode shown in FIG. 8 and a recommended setting transition time depending on whether the average power consumption value is larger than the reference value Wx. The CPU 301 executes the optimum power mode analysis process using the determination criterion of the RAM 303. For example, the CPU 301 determines whether the power mode holding time setting values (Ta to Tk) stored in the cartridge memories 44M to 44K on the process cartridges 40M to 40K are stored in the RAM 303 of the color image forming apparatus 1 in advance. Compared with (ta to tk), the recommended setting value (recommended setting transition time) is determined when it is larger or smaller.

  The operation panel 304 includes various operation keys, a display, and the like. From the operation keys, various operations necessary for causing the analysis device 300 to execute the optimum power mode analysis process are performed. Various information notified from 300 to the operator is displayed and output.

  The socket 306 is detachably mounted with the cartridge memories 44M to 44K removed from the process cartridges 40M to 40K, and the serial communication module 305 communicates with the cartridge memories 44M to 44K mounted to the socket 306, and the cartridge memory 44M The data in .about.44K is read, and the data is written in the cartridge memories 44M.about.44K.

  A plotter unit 308 is connected to the writing control unit 307, and the plotter unit 308 uses a predetermined image forming system such as an electrophotographic system or an ink ejection system. The writing control unit 307 controls the plotter unit 30 under the control of the CPU 301 to record and output various information, in particular, an analysis result in the optimum power mode analysis process on a recording sheet.

  The analysis apparatus 300 removes the cartridge memories 44M to 44K from the process cartridges 40M to 40K collected as described above, and the removed cartridge memories 44M to 44K are attached to the socket 306 to perform necessary operations. Is performed on the operation panel 304, the data is read from the cartridge memories 44M to 44K, and the optimum setting transition time optimum for the power mode at that time is determined according to the above-described determination criterion stored in advance in the RAM 303 or the ROM 302. The optimum power mode analysis process to be determined is executed.

  That is, as shown in FIG. 10, in the analyzing apparatus 300, when a predetermined operation is performed from the operation panel 304 and the optimum power mode analysis processing program is started (step S301), the CPU 301 causes the collected process cartridge 40M to be recovered. It is confirmed whether the cartridge memories 44M to 44K mounted on ˜40K are set in the socket 306 (step S302). When it is confirmed that the cartridge memories 44M to 44K are set in the socket 306, the operation from the operation panel 304 is confirmed. It is checked whether the start of analysis is instructed by a predetermined key operation (step S303).

  When an instruction to start analysis is given in step S303, the CPU 301 reads data from the cartridge memories 44M to 44K set in the socket 306, and based on the optimum setting determination table which is the determination criterion shown in FIG. The optimum setting power mode, that is, the optimum setting transition time is determined (step S304). That is, the CPU 301 determines whether the power mode holding time setting values (Ta to Tk) stored in the cartridge memories 44M to 44K on the process cartridges 40M to 40K are stored in the RAM 303 of the color image forming apparatus 1 in advance. Compared with (ta to tk), the recommended setting transition time is determined when it is large and when it is small.

  When determining the optimum setting transition time, the CPU 301 checks whether an output command has been issued by performing a predetermined operation from the operation panel 304 (step S305). The data relating to the determination, that is, the optimum setting transition time is written in the cartridge memories 44M to 44K and is recorded and output from the plotter unit 308 (step S306).

  Therefore, the setting transition time for controlling the transition between the power modes can be set to a more appropriate value according to the usage mode of the color image forming apparatus 1, and the power consumption can be further appropriately reduced. it can.

  In this manner, the cartridge memories 44M to 44K in which the optimum setting transition time is written are attached to the process cartridges 40M to 40K in which necessary parts have been replaced, and the cartridge memories 44M to 44K are attached again. When the process cartridges 40M to 40K are mounted on the color image forming apparatus 1 and a predetermined key operation is performed from the operation panel 204 of the color image forming apparatus 1, the cartridge memories 44M to 44K of the mounted process cartridges 40M to 40K Data is read out and written in the RAM 203, and each power mode is controlled in the same manner as described above based on the data written in the RAM 203.

  Therefore, it is possible to control the transition between the respective power modes based on the power management data optimized according to the usage mode, in particular, the set transition time, and it is possible to more appropriately reduce the power consumption.

  In addition, when the optimum power mode analysis program is stored in the ROM 202, the color image forming apparatus 1 can execute the optimum power mode analysis process by itself. It is possible to select the validity / invalidity of execution of the optimum power mode analysis processing at a predetermined timing (power mode optimum setting update function at any time) by a predetermined key operation.

  That is, as shown in FIG. 11, the CPU 201 of the color image forming apparatus 1 checks whether or not the power mode optimum setting optional update function is enabled by a predetermined key operation on the operation panel 204 (step S401). Thus, when the power mode optimum setting occasional update function is not set to be valid, the processing is ended as it is.

  If the power mode optimum setting occasional update function is set to be valid in step S401, the CPU 201 activates the optimum power mode analysis processing program in response to a predetermined operation from the operation panel 204 (step S402). Data is read into the RAM 203 from the cartridge memories 44M to 44K on the process cartridges 40M to 40K mounted on the forming apparatus 1, and the optimum setting power mode, that is, the optimum is set based on the optimum setting determination table of the RAM 203 shown in FIG. The setting transition time is determined, a value based on the table is written in the RAM 203, and the optimum power mode is set (step S403). That is, as described above, the CPU 201 stores the power mode holding time setting values (Ta to Tk) stored in the cartridge memories 44M to 44K on the process cartridges 40M to 40K in the RAM 203 of the color image forming apparatus 1 in advance. The recommended setting value (recommended setting transition time) is determined when it is larger or smaller than the determination criterion (ta to tk).

  Next, the CPU 201 waits for a display instruction to be displayed on the display of the operation panel 204 by a predetermined key operation on the operation panel 204 (step S404), and the data regarding the determination of the optimum setting power mode, that is, the optimum setting. The transition time is written in the cartridge memories 44M to 44K and displayed on the display of the operation panel 204 (step S405). When there is an instruction to exit from the display state on the operation panel 204 (step S406), a predetermined value is given from the operation panel 204. It is checked whether an output command has been performed by performing the operation (step S407).

  When an output command is issued in step S407, the CPU 201 causes the plotter unit 308 to record and output data relating to the determination of the optimum setting power mode, that is, the optimum setting transition time (step S408).

  Therefore, the color image forming apparatus 1 itself can always optimize the setting transition time according to the usage mode, and can further reduce power consumption more appropriately.

  Further, the color image forming apparatus 1 of the present embodiment has a power reduction effect calculation / output function, and the power reduction effect calculation / output function is enabled / disabled by a predetermined key operation on the operation panel 204. be able to. The color image forming apparatus 1 performs a predetermined key operation on the operation panel 204 to enable the power reduction effect calculation / output function, and when the predetermined key operation is performed on the operation panel 204, the power reduction effect is obtained. Perform calculation and output functions.

  That is, as shown in FIG. 12, the color image forming apparatus 1 performs a predetermined key operation on the operation panel 204 to enable the power reduction effect calculation / output function, and the predetermined key operation is performed on the operation panel 204. When it is performed (step S501), the CPU 201 reads data from the cartridge memories 44M to 44K on the process cartridges 40M to 40K mounted on the color image forming apparatus 1 into the RAM 203, and determines the optimum setting of the RAM 203 shown in FIG. By determining the optimal power mode setting based on the table, and subtracting or dividing the average power consumption value before and after the power setting update, using the value based on the optimal setting determination table as the average power consumption after the power setting update. A reduction effect is calculated (step S502).

  Next, the CPU 201 applies the power consumption value for each power mode, the power consumption value during the power mode holding time to the cartridge memories 44M to 44K and the RAM 203 on the process cartridges 40M to 40K mounted in the color image forming apparatus 1. The calculated power reduction effect is written together with the average power consumption value before and after the power setting update (step S503), and it is checked whether a display command on the display of the operation panel 204 is performed by a predetermined key operation on the operation panel 204 (step S503). S504).

  When a display instruction to the display of the operation panel 204 is performed in step S504, the CPU 201 displays and outputs a power reduction effect on the display of the operation panel 204 (step S505), and exits from the display state of the operation panel 204 on the display. If there is an instruction (step S506), it is checked whether a print output command has been issued by a predetermined key operation from the operation panel 204 (step S507).

  When a print output command is issued in step S507, the CPU 201 causes the plotter unit 308 to record and output the power reduction effect on a recording sheet (step S508).

  Therefore, the user can easily recognize the power reduction effect, and the usability can be improved.

  The power reduction effect calculation / output process is performed by the analysis apparatus 300 based on the power management data stored in the collected cartridge memories 44M to 44K, and the calculated power reduction effect is stored in the cartridge memories 44M to 44K. You may make it write and record-output on a paper.

  In this way, even in an image forming apparatus that does not have a power reduction effect calculation / output function, the user can easily recognize the power reduction (reduction) effect, and the usability can be improved. .

  The invention made by the present inventor has been specifically described based on the preferred embodiments. However, the present invention is not limited to the above, and various modifications can be made without departing from the scope of the invention. Needless to say.

  The present invention is applied to a process cartridge used in an image forming apparatus having a plurality of power modes, an image forming apparatus that detachably mounts the process cartridge, and a power management apparatus that optimizes process cartridge data. be able to.

1 is a schematic front view of an image forming apparatus according to an embodiment of a process cartridge, an image forming apparatus, and a power management apparatus of the present invention. FIG. 2 is an enlarged side sectional view of a process cartridge portion of FIG. 1. FIG. 2 is a circuit block configuration diagram of the image forming apparatus in FIG. 1. FIG. 2 is a power mode transition diagram of the image forming apparatus in FIG. 1. The figure which shows an example of the power consumption in each power mode memorize | stored in the cartridge memory etc. of the process cartridge of FIG. 3, elapsed time, and average power consumption. 3 is a flowchart illustrating an average power consumption calculation process for each change in power mode by the image forming apparatus of FIG. 1. 3 is a flowchart showing an average power consumption calculation process for each change in the power mode during the use period of the process cartridge by the image forming apparatus of FIG. 1. FIG. 4 is a diagram illustrating an example of determination criteria for optimum transition time in each power mode stored in a cartridge memory or the like of the process cartridge of FIG. 3. 1 is a schematic front configuration diagram of an analysis apparatus according to an embodiment of a process cartridge, an image forming apparatus, and a power management apparatus of the present invention. The flowchart which shows the optimal electric power mode analysis process by the analyzer of FIG. 3 is a flowchart showing optimum power mode analysis processing by the image forming apparatus of FIG. 1. 3 is a flowchart showing power reduction effect calculation / output processing by the image forming apparatus of FIG. 1.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Color image forming apparatus 2 Main body housing | casing 3 Paper discharge tray 10 Paper feed part 11 1st paper feed tray 12 2nd paper feed tray 13, 14 Paper feed roller 15, 16 Separation pad 17 Carrying roller 18 Registration roller 20 Plotter part 30 Photoconductor belt unit 31 to 33 Roller 34 Photoconductor belt 35 Photoconductor cleaning unit 36 Photoconductor waste toner bottle 40M, 40C, 40Y, 40K Process cartridge 41M, 41C, 41Y, 41K Toner bottle 42M, 42C, 42Y, 42K Development unit 43M, 43C, 43Y, 43K Cartridge 50 Intermediate transfer belt unit 51 Intermediate transfer belt 52 Roller 53 Intermediate transfer belt cleaning unit 54 Intermediate transfer waste toner bottle 55 Intermediate transfer roller 60 Secondary transfer unit 70 Writing unit 80 Charging Knit 90 fixing unit 100 discharge unit 201 CPU
202 ROM
203 RAM
204 Operation Panel 205 Serial Communication Module 206 I / O Control Unit 207 Various Sensors 208 Various Motors 209 Read Control Unit 210 Write Control Unit 211 Communication Control Unit 212 Network Control Unit 213 Bus 300 Analysis Device 301 CPU
302 ROM
303 RAM
304 Operation Panel 305 Serial Communication Module 306 Socket 307 Write Control Unit 308 Plotter Unit 309 Bus

Claims (3)

Comprising a plurality of different power modes of power consumption, in a process cartridge detachably attached to the image forming apparatus to transition in the transition time set between the respective power modes, at least the respective power modes, the respective power modes unit consumption amount per unit time, the number of transitions of the each power mode, the time maintenance of the power mode, the average power consumption is calculated from the amount of power consumption in the respective power modes, and set between the respective power modes in stores the power control data consisting of transition time, reduce power consumption in the image forming apparatus determined by performing a power mode optimization process based on the power management data by the control means provided in said image forming apparatus where optimum the data of the optimum setting transition time between power modes to the from the operation unit provided in the image forming apparatus A process cartridge, wherein a memory means is provided to be read or written under the control of the control means which receives the instruction. In the image forming apparatus which forms an image using a process cartridge and has a plurality of power modes having different power consumptions and makes a transition between the respective power modes with a set transition time, at least each of the process cartridges includes the process cartridge. power consumption amount per unit time in the power mode, the respective power modes, the number of transitions into the power mode, the time maintenance of the power mode, the average power consumption is calculated from the amount of power consumption in the respective power modes, and In order to reduce the power consumption in the image forming apparatus determined by the control unit provided in the image forming apparatus performing the power mode optimization process based on the power management data including the setting transition time between the power modes. data of the optimum setting transition time between optimal the respective power modes given from the operation unit provided in the image forming apparatus Shown is provided storage means for storing the control of the control means has received, said control means, on the basis of the data of the optimum set migration time instruction read from said memory means by receiving from the operation unit image An image forming apparatus, wherein the power consumption is reduced by controlling the success or failure of activation associated with the transition of each power mode related to each unit provided in the forming apparatus. A plurality of power modes with different power consumptions are provided, and by appropriately setting the transition time between the respective power modes, it is attached to a process cartridge that is detachably attached to an image forming apparatus that reduces power consumption, At least each power mode, power consumption per unit time in each power mode, number of transitions to each power mode, maintenance time of each power mode, average consumption calculated from power consumption in each power mode The power management data is read in response to a predetermined instruction from the external operation unit from the storage means for storing the power and the power management data including the setting transition time between the power modes, and the power management data is read based on the power management data. The power mode that determines the data of the optimal transition time between each power mode that is optimal for reducing the power consumption in the image forming apparatus. A control unit that performs optimization processing and stores data of the optimum setting transition time obtained by the power mode optimization processing in the storage unit, and the control unit receives an instruction from the external operation unit; Reducing the power consumption by controlling the success or failure of the activation associated with the transition of each power mode of each section provided in the image forming apparatus based on the data of the optimum setting transition time read from the storage means. A featured power management device.

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