JP2007295433A - Image forming apparatus, control method of image forming apparatus, program, and storage medium - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image forming apparatus capable of psychologically urging a user to actively utilize power-saving mode. <P>SOLUTION: The image forming apparatus is equipped with one or more apparatus functions and includes a standby mode on operation standby and the power saving mode, and is equipped with a power consumption measuring means for measuring power consumption. In the image forming apparatus, the measured values of the power consumption measuring means is sampled and recorded in a predetermined cycle in each of a mode by operations, while the apparatus functions, respectively, the standby mode and the power-saving mode are being executed. <P>COPYRIGHT: (C)2008,JPO&INPIT

Description

  The present invention relates to an image forming apparatus that includes one or more device functions, a standby mode that is in standby for operation, and an energy saving mode, a control method thereof, a program, and a storage medium.

  Conventionally, an image forming apparatus having at least an image forming function, such as a copying machine, a printer, a multifunction peripheral, and a facsimile machine, is provided with an energy saving mode for power saving so that power consumption during standby can be reduced. .

Further, Patent Document 1 discloses that the difference in power consumption between the normal operation mode (the operation mode in the non-energy saving mode (hereinafter the same)) and the energy saving mode can be presented to the user. Some have been proposed.
JP 2003-309684 A

  By the way, in the image forming apparatus having the energy saving mode, when a user operation is requested during the energy saving mode, it takes about 15 seconds to return from the energy saving mode to the normal operation mode. I can't do it and I have to wait.

  As described above, since it takes a relatively long time to return to the normal operation mode, some users disable the energy saving mode function so that the operation response of the image forming apparatus with respect to their own operation request is minimized. In addition, there is a situation where the operation is set.

  In this case, the energy saving mode provided in the image forming apparatus is not effectively used, and there is a problem that the energy saving effect cannot be obtained.

  In addition, in what was disclosed by patent document 1, although the power consumption amount for every operation mode was displayed based on the standard power reference value, and the statistics of the operation time were displayed or output, the power consumption is Since it fluctuates depending on the operation status of the apparatus, accurate information cannot be presented to the user, and on the contrary, a problem of inducing user distrust has occurred.

  SUMMARY An advantage of some aspects of the invention is that it provides an image forming apparatus that can be psychologically directed so that a user actively uses an energy saving mode.

  The present invention is an image forming apparatus provided with one or more device functions, a standby mode in standby for operation, and an energy saving mode, and includes power consumption measuring means for measuring power consumption. In each of the operation mode, standby mode, and energy saving mode being executed, the measured value of the power consumption measuring means is sampled and recorded at a predetermined period.

  In addition, the image forming apparatus includes one or more apparatus functions, a standby mode in operation standby, and an energy saving mode. The image forming apparatus includes power consumption measuring means for measuring power consumption. In each of the operation mode, standby mode, and energy saving mode being executed, the measured value of the power consumption measuring means is sampled and recorded at a predetermined cycle, and statistical information of a predetermined mode is recorded based on the recorded sampling value. The statistical information is generated and output.

  The power consumption measuring means measures AC power consumption and DC power consumption for each DC system, and the sampling value includes a sampling value of the AC power consumption and DC power consumption for each DC system. It is intended to be included.

  The power consumption measuring means measures AC power consumption and DC power consumption for each DC system, and the sampling value includes the AC power consumption, DC power consumption for each DC system, and each A sampling value of power efficiency for each DC system is included.

  In addition, charging information storage means for storing power charging information is provided, and the statistical information includes a power consumption reduction amount in the energy saving mode, and a power cost reduction amount determined based on the reduction amount and the power charging information. Is included.

  Further, the apparatus further comprises conversion information storage means for storing carbon dioxide-power conversion information, and the statistical information includes a reduction amount of power consumption in the energy saving mode, the reduction amount, and the carbon dioxide-power conversion information. The amount of carbon dioxide gas reduction determined is included.

  An image forming apparatus control method comprising one or more device functions, an operation standby mode, and an energy saving mode, comprising power consumption measuring means for measuring power consumption, wherein the device The measured value of the power consumption measuring means is sampled and recorded in a predetermined cycle in each of the operation mode, standby mode, and energy saving mode in which each function is being executed.

  An image forming apparatus control method comprising one or more device functions, an operation standby mode, and an energy saving mode, comprising power consumption measuring means for measuring power consumption, wherein the device In each of the operation-specific mode, standby mode, and energy-saving mode during which each function is being executed, the measured value of the power consumption measuring means is sampled and recorded at a predetermined period, and a predetermined mode is determined based on the recorded sampling value. Statistical information is created and the statistical information is output.

  Further, the power billing information is stored, and the statistical information includes a power consumption reduction amount in the energy saving mode and a power cost reduction amount determined based on the reduction amount and the power billing information. Is.

  Furthermore, while storing carbon dioxide-power conversion information, the statistical information includes a reduction amount of power consumption in the energy saving mode, and a carbon dioxide reduction determined based on the reduction amount and the carbon dioxide-power conversion information. The amount is included.

  In addition, the program is implemented in an image forming apparatus having one or more device functions, a standby mode in standby mode, and an energy saving mode, and a mode for each operation in which each of the device functions is being executed. In each of the mode and the energy saving mode, the program is characterized in that the measured value of the power consumption of the apparatus is sampled and recorded at a predetermined period.

  In addition, there is a program implemented in an image forming apparatus having one or more device functions, an operation standby mode, and an energy saving mode, each of the device functions being operated, a standby mode In each of the energy saving modes, the measured value of the power consumption of the apparatus is sampled and recorded at a predetermined period, statistical information of a predetermined mode is created based on the recorded sampling value, and the statistical information is output Is a program characterized by

  A storage medium storing the program according to claim 11 or 12.

  Therefore, according to the present invention, the power consumption for each operation mode can be measured and presented to the user, so that a highly reliable power consumption amount according to the operating status of the apparatus can be presented to the user. The energy saving effect can be recognized by the user, and as a result, the user can be guided to actively use the energy saving mode.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

  FIG. 1 shows an example of an image forming apparatus according to an embodiment of the present invention. The image forming apparatus includes a copying function, an image reading function, a printer function, a network printer function, a scan-to-email function, and the like.

  In this figure, the image forming apparatus includes a system management unit US that controls operation of the apparatus, an engine unit UE for realizing an image reading function and an image forming function, and the system management unit US and the engine unit UE. The power supply unit UP for supplying power is composed of three units.

  In the system management unit US, the system control unit 1 is for controlling the operation of each unit of the image forming apparatus, and the operation display unit 2 is for the user to operate the image forming apparatus. The battery 3 includes various operation keys and a display device, and the battery 3 drives a built-in memory (not shown) and a clock circuit (not shown) included in the system control unit 1 even when the main power is turned off. Is.

  The magnetic disk device 4 is for storing, for example, various programs executed by the system control unit 1, various sampling data such as a power consumption history information table (described later), and the host interface circuit 5 is a personal computer. The network communication unit 6 is connected to an external host device such as a device and exchanges various data such as print job information with the external host device. The network communication unit 6 is connected to a network such as a local area network, for example. In addition, various information is exchanged with other terminal devices via the network.

  In the engine unit UE, the engine control unit 7 controls the operation of the engine unit UE, exchanges various information with the system control unit 1, and controls the operation mode, the operation timing, and the like.

  The document reading unit 8 is for realizing a scanner function, and the automatic document transport unit 9 is for feeding a read document to the document reading unit 8 one by one.

  The writing unit 10 is for writing an electrostatic latent image on a photosensitive unit (not shown) of the image forming drive unit 12 using, for example, a laser beam, and the paper feed tray 11 is an image forming drive unit. The image forming drive unit 12 uses an electrostatic photographic process to toner-develop the electrostatic latent image written on the photosensitive unit, and the toner image Is transferred to the recording paper and then heat-fixed on the recording paper. The heater driving unit 14 drives the fixing heater of the image forming driving unit 12. The heater drive unit 14 is controlled in operation by the engine control unit 7.

  In the power supply unit UP, the commercial power is supplied to the DC power supply units 16 and 17 through the AC power detection unit 15 and to the image forming drive unit 12 through the heater drive unit 14.

  The AC power detection unit 15 is for detecting the power of the commercial power source consumed by the apparatus, and the detection value SD1 is output to the system control unit 1. More specifically, the AC power detection unit 15 is divided into a voltage detection unit and a current detection unit. Two values of voltage and current are read, and the result of multiplication is recorded as power consumption. When recording, not only the multiplication result but also the original data of voltage and current may be recorded as they are. In addition, the specific detection of the voltage is also possible by full-wave rectification of L (line) and N (neutral) of a general commercial power supply, reducing the voltage with a transformer, and reading the value by A / D conversion. good. Specific detection of the current may be performed by converting the current value flowing through L (line) into magnetic flux, converting it into voltage, and reading it with A / D conversion, or inserting a current value detection resistor. You may read. Alternatively, a method of reading by inserting an element whose temperature changes with a flowing current may be used.

  The DC power supply unit 16 is based on the input commercial power supply, and the DC power supply VC1 (for example, 5 volts) for the logic circuit of the engine unit UE and the DC power supply VD1 for the drive unit required for the engine unit UE (for example, DC power sources VC1 and VD1 are respectively supplied to necessary portions of the engine unit UE. The operation of the DC power supply unit 16 is controlled based on the signal SS1 output from the system control unit 1.

  The DC power supply unit 17 includes a DC power supply VC2 (for example, 5 volts) for the logic circuit of the system management unit US and a DC power supply VD2 for the drive unit necessary for the system management unit US based on the commercial power input. For example, the DC power sources VC2 and VD2 are respectively supplied to necessary portions of the system management unit US. The DC power supply unit 17 always operates when a main power switch (not shown) is turned on.

  With the above configuration, the operation of the present embodiment will be described next with reference to FIG.

(1) At startup First, when the main power switch is turned on, commercial power is input to the power supply unit, and the DC power supply unit 17 is first started to supply power to the system management unit US.

  The CPU (central processing unit; not shown) of the system control unit 1 reads the initial program in the boot memory, reads the control program stored in the magnetic disk device 4, and starts the entire image forming apparatus.

  Then, the system control unit 1 turns on the DC power supply unit 16 to supply power to the engine unit UE. At the same time, the data of the AC power detection unit 15 is read, and the power consumption data and the time are recorded in the memory of the system control unit 1. The operation mode is a rising mode.

  Thereafter, the power consumption data is read from the AC power detection unit 15 and recorded in the memory at regular intervals. In the present embodiment, for example, data is read and recorded at a cycle of 1 second.

  When the amount of recorded data reaches a certain level or more, the data in the memory is written to the magnetic disk device 4 and the written data is erased from the memory.

  Here, the recording cycle is not 1 second, but may be a shorter cycle, for example, in units of 0.1 seconds, or may be a long cycle, for example, 3 seconds. However, even if the cycle is shortened too much, the processing load on the system control unit is increased, and the amount of memory consumed and the storage capacity required for the magnetic disk device 4 are increased. There is not much merit to raise.

  Conversely, if the cycle is too long, the processing load on the system control unit 1 is reduced and the amount of memory consumed and the storage capacity required for the magnetic disk device 4 are reduced. However, there is an error between the grasped power consumption and the actual power consumption. It can grow. Note that a method may be used in which data is read at a constant period, and when the data reaches a certain number of times, the data is averaged and recorded in the memory or the magnetic disk device 4.

  Now, after starting the recording of the power consumption data, the system control unit 1 gives an instruction to the engine control unit 7, the document reading unit 8 connected to the engine control unit 7, the automatic conveyance unit 9, the writing unit 10, the paper feed The initial operation of the tray 11, the image forming drive unit 12, and the post-processing peripheral device 13 is performed. Further, the heater driving unit 14 is driven to raise the temperature of the fixing heater of the image forming driving unit 12.

  When the initial operation is performed and the fixing heater reaches a target temperature at which copying can be performed, the system control unit 1 recognizes that the mode has been switched from “rise” to “standby mode”, and records “standby mode” and the switching time. To do. Further, the data of the AC power detection unit 15 is read and recorded at a cycle of 1 second as in the “rise” mode. The state is maintained in the standby mode until switched to another operation mode.

(2) Copy output mode When a document is placed on the contact glass of the document reading unit 8 or placed on the automatic document transport unit 9 and a copy start button (not shown) of the operation display unit 2 is pressed, the system control unit 1 Detects the copy start and gives a command to the engine control unit 7.

  As a result, the engine control unit 7 operates the document reading unit 8 to send the read document data to the system control unit 1 and store it in the memory or the magnetic disk device 4.

  Next, the data in the memory or magnetic disk device 4 is sent to the writing unit 10 and the image forming drive unit 12 is driven to perform printing.

  The system control unit 1 recognizes that the mode has been switched to the “copy mode” simultaneously with the start of copying, and records the “copy mode” and the switching time thereof. Further, the data of the AC power detection unit 15 is read and recorded at a cycle of 1 second as in the “standby mode”.

  When copying is complete, the mode switches to standby mode. The subsequent processing is the same as when “rise” → “standby mode” is switched at the time of startup.

(3) Print Output Mode When a print instruction and print data are received from an interface such as the network communication unit 6 or the host interface circuit 5, the system control unit 1 gives a command to the engine control unit 7.

  As a result, the engine control unit 7 sends print data to the writing unit 10 and drives the image forming drive unit 12 to perform printing. The system control unit 1 switches the mode to “print mode” simultaneously with the reception of the print instruction data, and records “print mode” and the switching time.

  Further, the data of the AC power detection unit 15 is read and recorded at a cycle of 1 second as in the “standby mode”. When printing is completed, the mode is switched to the standby mode. The subsequent processing is the same as when “rise” → “standby mode” is switched at the time of startup.

(4) Scan Mode When the user places a document on the contact glass or places a document on the automatic document feeder, sets the operation display unit 2 to the scan mode, and presses a start button (not shown), the system control unit 1 Detects the scan start and gives a command to the engine control unit 7.

  As a result, the engine control unit 7 operates the document reading unit 8 to sequentially send the read document data to the system control unit 1 to be stored in the memory or the magnetic disk device 4. The system control unit 1 detects that the start has been pressed, and simultaneously recognizes that the mode has been switched to the “scan mode”, and records the “scan mode” and the switching time.

  Further, the data of the AC power detection unit 15 is read and recorded at a cycle of 1 second as in the “standby mode”. When the scan is completed, the mode is switched to the standby mode. The subsequent processing is the same as when “rise” → “standby mode” is switched at the time of startup.

  Note that the scan can be started by sending a start instruction from the personal computer through the network communication unit 6 in addition to pressing the start button of the operation display unit 2. In that case, the process is the same.

(5) Energy saving mode A (low power mode)
A fixing unit (not shown) is mounted on the image forming drive unit 12 (a fixing heater is mounted inside). In the standby mode, control is performed to maintain a temperature at which copying can be immediately performed.

  For example, in the standby mode, control is performed to maintain a temperature of 170 ° C. In order to maintain this temperature, the image forming apparatus consumes a large amount of power. Therefore, if the image forming apparatus is not used much, it is recommended that the temperature of the copy and print be lowered by several tens of degrees Celsius from the temperature at which copying and printing can be performed immediately. You can save money.

  As described above, there is a mode in which the temperature of the fixing unit is lowered to some extent, the backlight of the operation display unit 2 is turned off, or a motor in the image forming apparatus is stopped to save power. One of them is the low power mode.

  In the low power mode, the operation unit of the image forming apparatus can be set to automatically shift if the image forming apparatus is not used for a certain period of time (it is possible to set the time until transition and whether or not to allow transition).

  When shifting to the low power mode, the system control unit 1 recognizes that the mode has been switched to the “low power mode”, and records the “low power mode” and the switching time.

  Further, the data of the AC power detection unit 15 is read and recorded at a cycle of 1 second as in the “standby mode”. When any operation of the image forming apparatus is performed or an instruction is received from the host interface circuit 5 and the network communication unit 6, the low power mode is canceled.

  Subsequent processing is the same as (1) to (4) above. Note that, after the low power mode is canceled, the “rise mode” is handled until the temperature of the fixing unit reaches a certain temperature at which copying can be immediately performed.

(6) Energy saving mode B (sleep mode)
In this mode, the power consumption is greatly reduced compared to the low power mode.

  That is, in this embodiment, the temperature maintenance control of the fixing unit is not performed in the sleep mode, the DC power supply unit 16 is also turned off, only the DC power supply unit 17 is turned on, and the operation display unit 2 is also turned off.

  By turning on only the DC power supply unit 17, only the system management unit US operates, and when data such as a print instruction is received from the host interface circuit 5 and the network communication unit 6, the sleep mode is immediately canceled, When the image forming apparatus is started and printing is started, or when an instruction to send internal data of the image forming apparatus is received, the data managed by the system control unit 1 is transferred to the host interface circuit 5 and the network communication unit 6. Send through.

  As for the transition of the sleep mode, the transition time and the transition presence / absence can be set on the operation display unit 2 as in the low power mode. The sleep mode can also be entered by pressing a sub power key (not shown) provided on the operation display unit 2.

  When the system control unit 1 shifts to the sleep mode, the system control unit 1 recognizes that the mode has been switched to the “sleep mode”, and records the “sleep mode” and the switching time. Further, the data of the AC power detection unit 15 is read and recorded at a cycle of 1 second as in the “standby mode”.

  The method for canceling the sleep mode is to receive an instruction from the host interface circuit 5 and the network communication unit 6 or to press the power supply subkey described above. Processing after canceling the sleep mode is the same as (1) to (4) described above. Note that, after the sleep mode is canceled, the “rise mode” is handled until the temperature of the fixing unit reaches a certain temperature at which copying can be immediately performed.

(7) Energy saving mode C (off mode)
This is an energy saving mode that does not wait for data reception from the host interface circuit 5 and the network communication unit 6. That is, in the off mode of this embodiment, the temperature maintenance control of the fixing unit is not performed, the DC power supply unit 16 is also turned off, and only the DC power supply unit 17 is turned on. Furthermore, only a small part of the system control unit 1 is operating in the system management unit US. In this way, significant power reduction is achieved.

  As for the transition of the off mode, the transition time and the transition presence / absence are set on the operation display unit 2 as in the low power mode and the sleep mode. It is also possible to shift to the off mode by pressing the above-described sub power key (in this case, when an interface such as a LAN is invalid. When the interface function is valid, the mode is shifted not to the off mode but to the sleep mode).

  When the system control unit 1 shifts to the off mode, the system control unit 1 recognizes that the mode has been switched to the “off mode”, and records the “off mode” and the switching time. In addition, since the reading function of the AC power detection unit 15 is also in a non-operating state, power consumption is not detected.

  However, since the power consumption in the off mode is completely off and the motor and fan are not driven, the power consumption is almost constant, so it is sufficient to use table data recorded in advance in the memory. Can be substituted.

  For example, the power consumption in the off mode is 10W. Only the off mode transition and the switching time are recorded, and the system control unit operates only a part of the functions of the system control unit and shifts most of the other functions to the non-operating state as described above. Migrate).

  The method for canceling the off mode is to press the power supply subkey described above.

  The processing after the power sub key is pressed and the off mode is canceled is the same as the operation flow after the main power switch is turned on. Therefore, after the off mode is canceled, the “rise mode” is handled until the temperature of the fixing unit reaches a certain temperature at which copying can be immediately performed.

(8) Print Output + Scan Mode The image forming apparatus of the present embodiment can perform a scan operation in parallel during print output.

  The print output here is the same in the copy output mode when the document reading is completed and only the copy print operation is performed. Conversely, the same applies to the case where print output is performed via the host interface circuit 5 and the network communication unit 6 during the scanning operation.

  At the time of print output, the system control unit recognizes that it is “print mode”, records “print mode” and its switching time, and detects and records power consumption at a cycle of 1 second.

  At that time, if the scan operation is performed in parallel, during the parallel operation, the difference between the power before the parallel operation and the power during the parallel operation is the power consumption in the scan mode, and the power equivalent to the power before the parallel operation is consumed in the print mode. Record as power.

  In FIG. 2, the print output mode operates first, and the scanner operation occurs while printing continues. By calculating the power difference before and after the occurrence of the scan operation as shown in the figure, it is possible to separate the power consumption of the print output from the power consumption of the scan. Record individually.

  In FIG. 2, the print output and the scan are performed in parallel, but the print output is finished first in the middle. At this time, the recording of the power consumption of the print output is completed, and thereafter, the power consumption is only for scanning.

  The first half of FIG. 2 also shows the transition of power consumption during startup, standby, and copying. The image forming apparatus records the power consumption at a constant cycle. When the power value is plotted on the vertical axis and time is plotted on the horizontal axis, the power is plotted as shown in FIG.

  In the present embodiment, the power value detected by the AC power detection unit 15 is stored in a power consumption history information table as shown in FIG. The power consumption history information table stores a plurality of power consumption history information created for each time-series operation mode of the image forming apparatus.

  The power consumption history information includes, for example, operation mode information, time information indicating a measurement start time, a sampling period (option), and a plurality of power sampling values, as shown in FIG.

  Here, as the power sampling value, the power value detected by the AC power detection unit 15 may be used as it is, or the voltage value, current value detected by the AC power detection unit 15 as shown in FIG. The calculated power value may be used.

  The sampling period is fixed to 1 second, for example, but a different sampling period can be set for each operation mode. In that case, a value representing the set sampling period is stored in the sampling period of the power consumption history information. Further, when the sampling period is fixed, the value of this sampling period is not referred to, and therefore, for example, an invalid value may be set.

  FIG. 4 shows an example of processing related to sampling of power consumption history information.

  First, when the main power switch is turned on (process 101), a predetermined activation process is executed (process 102), and the initialization process of each unit is started as described above (process 103).

  Here, the rising mode is set as the operation mode (process 104), and the operation mode and time are recorded in the power consumption history information (process 105). Thereafter, the power consumption is sampled at a cycle of 1 second until the initial process is completed, and sequentially recorded in the power consumption history information as a power sampling value (NO loop of processing 106 and determination 107).

  When the initial process is completed and the result of determination 107 is YES, the standby mode is set as the operation mode (process 108), and the operation mode and time are recorded in the power consumption history information (process 109). Thereafter, until the mode change is detected, the power consumption is sampled at a cycle of 1 second, and sequentially recorded in the power consumption history information as a power sampling value (NO loop of processing 110 and determination 111).

  Thereafter, when the mode change is detected and the result of determination 111 is YES, the changed operation mode is set as the operation mode (process 112), and the operation mode and time are recorded in the power consumption history information (process 113). . Thereafter, until the mode change is detected again, the power consumption is sampled at a cycle of 1 second, and sequentially recorded in the power consumption history information as a power sampling value (processing 114, NO loop of decision 115).

  When a mode change is detected and the result of determination 115 is YES, the process returns to process 112 and the subsequent processes are repeatedly executed.

  Next, how to use the power consumption history information data thus recorded will be described.

  First, as the accuracy of the detected electric energy, for example, as shown in FIG. 5, a value rounded to the first decimal place can be applied. In addition, as the accuracy of the accumulated power amount in the same mode, a value rounded off to the first decimal place can be applied.

  Then, when the user performs display setting from the operation display unit 2, statistical information of power consumption for each hour is created, and the statistical information as shown in FIG. 6A is displayed. The power consumption shown in the figure is the integrated power display as described above, but the average power may be displayed.

  Further, as shown in FIG. 7B, statistical information summarizing power consumption may be displayed for each operation mode in units of one day. The power consumption in the figure is integrated power. In order to confirm the effect of the energy saving mode, it is effective to calculate and display the effect amount of the low power mode and the sleep mode with reference to the detected value of the power consumption in the standby mode.

Here, the effect amount is calculated by calculating the average power in the standby mode of the day, and calculating the power that must be consumed if the low power mode and the sleep mode are each in the standby mode. To do. Therefore, the effect amount can be calculated by subtracting the difference between the detected power consumptions of the low power mode and the sleep mode as follows.
Average power in standby mode: 800 Wh / h ÷ 2 hours = 400 Wh
Effective amount of low power mode: 5 hours × 400 Wh / h-600 Wh / h = 1400 Wh / h
Effective amount of sleep mode: 3 hours × 400 Wh / h-120 Wh / h = 1080 Wh / h

  By the way, for example, when the operation time of the standby mode of the day is too short, such as 10 minutes or less, there is a case where the variation is inappropriate for use as reference data for the effect amount. Therefore, in the case of 10 minutes or less, the standby mode average power is stored in advance as table data. When the standby mode operation time of the day is shorter than 10 minutes, the average power of the table data is used as reference data. It may be used to calculate the effect amount.

  The same applies to an image forming apparatus that shifts to the off mode instead of the sleep mode, and FIG. 6C shows a display example in that case.

  An example of statistical data processing is shown below. In addition, although the following description is an example of processing of power consumption, a power charge may be calculated or CO2 may be calculated and displayed in a graph (described later).

  Example 1 An example in which weekly power is processed is shown in FIGS. 7 (a) and 7 (b). In this case, what happens when the energy saving (low power, sleep, off) mode is not used may be replaced with the estimated power in the standby mode, and the power when the energy saving mode is not used may be juxtaposed.

  Example 2) An example of processing of daily power is shown in FIGS. 8 (a) and 8 (b). In this case, what happens when the energy saving (low power, sleep, off) mode is not used may be replaced with the estimated power in the standby mode, and the power when the energy saving mode is not used may be juxtaposed.

  Example 3) An example in which an integrated value of electric power for one month is obtained is shown in FIGS. What happens when the energy saving (low power, sleep, off) mode is not used may be replaced with the estimated power in the standby mode, and the power when the energy saving mode is not used may be juxtaposed.

  Example 4 FIG. 11 shows an example of processing a daily power transition diagram. In this case, it may be possible to process and display a power transition diagram for one day or a specified time range (for example, from 1 pm to 2 pm).

  By the way, in order to inform the user of the effect of the energy saving mode, for example, it corresponds to the energy saving effect, that is, the charge (cost) reduced by using the energy saving mode and the power reduced by using the energy saving mode. It is effective to display the amount of carbon dioxide gas (CO2 weight) that can be reduced.

  Therefore, for example, a power cost setting screen as shown in FIG. 12 is displayed to allow the user to set and input the power cost. Further, a setting screen for the CO2 emission coefficient as shown in FIG. 13A is displayed, and the user is allowed to set and input the CO2 emission coefficient (carbon dioxide gas amount−electric power conversion value).

  Then, as shown in FIGS. 14A and 14B, the power cost reduction amount, the CO2 emission amount, and the CO2 reduction amount are written together in the power consumption history display.

  Here, the following formula can be used to calculate the power cost.

    {(Unit price x Monthly power consumption) x (Fuel adjustment cost x Monthly power consumption)} x (1 + consumption tax)

  Further, the same contents as the statistical information displayed as described above are printed out by setting the operation display unit 2, or the statistical information is printed out from a personal computer or the like via the host interface circuit 5 and the network communication unit 6. And may be printed on paper.

  Further, when an instruction is given from a personal computer or the like via the host interface circuit 5 and the network communication unit 6, the statistical information of the image forming apparatus is read out to the personal computer or the like, or the power consumption data per unit time is directly taken out and the personal computer is retrieved. It is also possible to display a transition graph of power consumption in time series on the screen or the like.

  Further, as shown in FIGS. 13B and 13C, the power consumption history information stored in the magnetic disk device 4 when the storage period or storage amount is set by the user and the storage period or storage amount is exceeded. It can also be set to clear the table.

  In this way, in this embodiment, the operation mode history is kept while monitoring the power consumption at a constant cycle, so the power consumption for each operation mode is not a guideline value, but the actual power consumption can be grasped. It is possible to provide the user with highly reliable power data.

  In addition, since there is a function to display a list of the operation time and actual power consumption for each operation mode, it is confirmed how effectively the user is using the image forming device, especially the energy saving mode. Can increase the user's awareness of energy saving.

  In addition, since there is a function to print out the operation time and actual power consumption for each operation mode on paper, how effective the user is using the image forming device, especially whether the energy saving mode can be used effectively. , Management and grasping, can raise the user's awareness of energy saving.

  In addition, there is a function that allows the user to capture image data such as operation time, actual power consumption, and power consumption in time order for each operation mode via a host interface circuit 5 and a network communication unit 6. It is possible to manage and grasp the usage status of devices and power transitions, confirm energy saving effects and improve energy saving awareness.

  Further, since the detection means is in the AC unit of the apparatus, the power of the entire image forming apparatus can be detected.

  In addition, since each voltage and current is detected, not only power but also voltage / current can be displayed, output, and data can be transmitted, and the user can check the stable voltage supply status and current transition status. Can do.

  FIG. 15 shows an example of an image forming apparatus according to another embodiment of the present invention. The image forming apparatus includes a copying function, an image reading function, a printer function, a network printer function, a scan-to-email function, and the like. In the figure, the same parts as those in FIG. 1 and corresponding parts are denoted by the same reference numerals.

  In this figure, the image forming apparatus includes a system management unit US that controls operation of the apparatus, an engine unit UE for realizing an image reading function and an image forming function, and the system management unit US and the engine unit UE. The power supply unit UP for supplying power is composed of three units.

  In the system management unit US, the system control unit 1 is for controlling the operation of each unit of the image forming apparatus, and the operation display unit 2 is for the user to operate the image forming apparatus. The battery 3 includes various operation keys and a display device, and the battery 3 drives a built-in memory (not shown) and a clock circuit (not shown) included in the system control unit 1 even when the main power is turned off. Is.

  The magnetic disk device 4 is for storing, for example, various programs executed by the system control unit 1, various sampling data such as a power consumption history information table (described later), and the host interface circuit 5 is a personal computer. The network communication unit 6 is connected to an external host device such as a device and exchanges various data such as print job information with the external host device. The network communication unit 6 is connected to a network such as a local area network, for example. In addition, various information is exchanged with other terminal devices via the network.

  In the engine unit UE, the engine control unit 7 controls the operation of the engine unit UE, exchanges various information with the system control unit 1, and controls the operation mode, the operation timing, and the like.

  The document reading unit 8 is for realizing a scanner function, and the automatic document transport unit 9 is for feeding a read document to the document reading unit 8 one by one.

  The writing unit 10 is for writing an electrostatic latent image on a photosensitive unit (not shown) of the image forming drive unit 12 using, for example, a laser beam, and the paper feed tray 11 is an image forming drive unit. The image forming drive unit 12 uses an electrostatic photographic process to toner-develop the electrostatic latent image written on the photosensitive unit, and the toner image Is transferred to the recording paper and then heat-fixed on the recording paper. The heater driving unit 14 drives the fixing heater of the image forming driving unit 12. The heater drive unit 14 is controlled in operation by the engine control unit 7.

  In the power supply unit UP, commercial power is applied to the heater drive unit 14 via the AC power detection unit 20 and to the DC power supply units 16 and 17 via the AC power detection unit 21.

  The AC power detection unit 20 is for detecting the power of the commercial power source consumed by the fixing heater of the image forming drive unit 12, and the detection value SD 1 is output to the system control unit 1. The AC power detection unit 21 is for detecting the power of the commercial power consumed by the DC power supply units 16 and 17, and the detection value SD 2 is output to the system control unit 1.

  The DC power supply unit 16 is based on the input commercial power supply, and the DC power supply VC1 (for example, 5 volts) for the logic circuit of the engine unit UE and the DC power supply VD1 for the drive unit required for the engine unit UE (for example, The DC power sources VC1 and VD1 are supplied to the necessary portions of the engine unit UE via the DC power detection units 22 and 23, respectively. The operation of the DC power supply unit 16 is controlled based on the signal SS1 output from the system control unit 1.

  The DC power detection units 22 and 23 detect voltage values and current values of the DC power sources VC1 and VD1, and the detection values SD3 and SD4 are output to the system control unit 1.

  The DC power supply unit 17 includes a DC power supply VC2 (for example, 5 volts) for the logic circuit of the system management unit US and a DC power supply VD2 for the drive unit necessary for the system management unit US based on the commercial power input. For example, the DC power sources VC2 and VD2 are supplied to necessary portions of the system management unit US via the DC power detection units 24 and 25, respectively. The DC power supply unit 17 always operates when a main power switch (not shown) is turned on.

  The DC power detection units 24 and 25 detect voltage values and current values of the DC power sources VC2 and VD2, and the detection values SD5 and SD6 are output to the system control unit 1.

  In more detail, the AC power detection units 20 and 21 are divided into a voltage detection unit and a current detection unit. Two values of voltage and current are read, and the result of multiplication is recorded as power consumption. When recording, not only the multiplication result but also the original data of voltage and current may be recorded as they are.

  In this embodiment, the detection values SD1, SD2, SD3, SD4, SD5, and SD6 are recorded as one unit as power sampling values in the power consumption history information of the power consumption history information table.

  In this embodiment, the DC power supply units 16 and 17 sample the power value on the input side (primary side) and the power value on the output side (secondary side), so that the conversion efficiency to DC voltage is improved. Can be calculated.

  Therefore, for example, as shown in FIGS. 16A and 16B, when displaying statistical information, the conversion efficiency of the DC power supply can be written together.

  Here, the conversion efficiency of a DC power supply generally has a high conversion efficiency when the load is high, and the conversion efficiency is low when the load is low. Therefore, in the example of FIGS. 16A and 16B, when the drive part of the image forming apparatus is large, that is, when the power consumption is large, the copy and print modes are 80% of the high conversion efficiency. In the standby mode and the low power mode, the conversion efficiency is 50%.

  In the sleep mode, the DC power supply 16 is turned off and the power is supplied from the DC power supply 17 to the system management unit US as usual, so that the conversion efficiency is 70%.

  The reason why two DC power supplies are provided as in the present embodiment is that high conversion efficiency is obtained and the loss of the DC power supply is reduced in the energy saving mode in which one of the two DC power supplies is turned off, such as in the sleep mode. Because. The effect can be seen in FIG.

  Note that the detection of voltage and current on the DC power supply output side is not directly related to the electricity charge, etc., so the measurement is not every 1 second cycle, but a long cycle such as 10 seconds, or after a certain time has passed since the mode was switched. Reading and recording the detected value in a cycle such as only once is sufficient for use. If the data storage capacity and the processing capacity of the system control unit are sufficiently large, the numerical value of the output unit of the DC power supply may be detected of course at a cycle of 1 second.

  In this way, in this embodiment, by detecting the output power of the DC power supply, it is possible to grasp the conversion efficiency and loss of the DC power supply, and to know the effective utilization of the DC power supply of the image forming apparatus. It is possible to improve the user's awareness of energy saving.

  Also, by using two detection means for the output part of the DC power supply, voltage and current, it is possible to grasp the output power with little error.

  In the above-described embodiment, the case where the present invention is applied to a so-called multi-function image forming apparatus having a copying function, an image reading function, a printer function, a network printer function, a scan-to-email function, etc. has been described. However, the present invention can be similarly applied to apparatuses having other configurations as long as the image forming apparatus has at least an energy saving mode.

1 is a block diagram showing an example of an image forming apparatus according to an embodiment of the present invention. 4 is a time chart for explaining the operation of the image forming apparatus. Schematic which showed an example of a power consumption log | history information table, power consumption log | history information, and a power sampling value. The flowchart which showed an example of the process regarding sampling of power consumption historical information. Schematic which showed an example of the power consumption at the time of copy operation. Schematic which showed an example of the power consumption history display. Schematic which showed the example of a display. The schematic diagram which showed the example of a statistics display. Schematic which showed the example of a display of an integrated value. Schematic which showed an example of the other display form of the example of a display of an integrated value. Schematic which showed the example of a graph display. Schematic which showed an example of the power cost setting screen. Schematic which showed an example of the setting screen of a CO2 emission coefficient, the setting screen of a storage period, and the setting screen of a storage amount. Schematic which showed the other example of the power consumption log | history display. FIG. 6 is a block diagram showing an example of an image forming apparatus according to another embodiment of the present invention. Schematic which showed the other example of a display of statistical information.

Explanation of symbols

US system management unit UE engine unit UP power supply unit 1 system control unit 2 operation display unit 4 magnetic disk device 5 host interface circuit 6 network communication unit 7 engine control unit 12 image formation drive unit 14 heater drive unit 15, 20, 21 AC power Detection unit 22, 23, 24, 25 DC power detection unit

Claims (13)

An image forming apparatus having one or more device functions, a standby mode for standby operation, and an energy saving mode,
Power consumption measuring means for measuring power consumption is provided,
An image forming apparatus, wherein the measured value of the power consumption measuring means is sampled and recorded at a predetermined period in each of the operation mode, standby mode, and energy saving mode during each execution of the apparatus function. An image forming apparatus having one or more device functions, a standby mode for standby operation, and an energy saving mode,
Power consumption measuring means for measuring power consumption is provided,
In each of the operation-specific mode, standby mode, and energy-saving mode each executing the device function, the measured value of the power consumption measuring means is sampled and recorded at a predetermined cycle,
An image forming apparatus, wherein statistical information of a predetermined mode is created based on the recorded sampling value, and the statistical information is output. The power consumption measuring means measures AC power consumption and DC power consumption for each DC system,
The image forming apparatus according to claim 1, wherein the sampling value includes a sampling value of the AC power consumption and a DC power consumption for each DC system. The power consumption measuring means measures AC power consumption and DC power consumption for each DC system,
3. The image according to claim 1, wherein the sampling value includes the AC power consumption, the DC power consumption for each DC system, and the sampling value of the power efficiency for each DC system. Forming equipment. Furthermore, it comprises a billing information storage means for storing power billing information,
4. The statistical information includes a power consumption reduction amount in the energy saving mode, and a power cost reduction amount determined based on the reduction amount and the power billing information. 5. The image forming apparatus according to 4. Furthermore, it comprises conversion information storage means for storing carbon dioxide gas-power conversion information,
4. The statistical information includes a reduction amount of power consumption in the energy saving mode and a carbon dioxide gas reduction amount determined based on the reduction amount and the carbon dioxide-power conversion information. The image forming apparatus according to claim 4. A control method for an image forming apparatus having one or more device functions, a standby mode for standby operation, and an energy saving mode,
Power consumption measuring means for measuring power consumption is provided,
Control of an image forming apparatus, wherein the measured value of the power consumption measuring means is sampled and recorded at a predetermined period in each of the operation mode, standby mode, and energy saving mode during execution of each of the apparatus functions. Method. A control method for an image forming apparatus having one or more device functions, a standby mode for standby operation, and an energy saving mode,
Power consumption measuring means for measuring power consumption is provided,
In each of the operation-specific mode, standby mode, and energy-saving mode each executing the device function, the measured value of the power consumption measuring means is sampled and recorded at a predetermined cycle,
A control method for an image forming apparatus, comprising: generating statistical information in a predetermined mode based on the recorded sampling value and outputting the statistical information. In addition to storing power billing information,
9. The control of an image forming apparatus according to claim 8, wherein the statistical information includes a power consumption reduction amount in the energy saving mode and a power cost reduction amount determined based on the reduction amount and the power billing information. Method. Furthermore, while storing carbon dioxide-electric power conversion information,
9. The image formation according to claim 8, wherein the statistical information includes a reduction amount of power consumption in the energy saving mode, and a reduction amount of carbon dioxide determined based on the reduction amount and the carbon dioxide-power conversion information. Control method of the device. A program that has one or more device functions, is mounted on an image forming apparatus that has a standby mode during standby for operation, and an energy saving mode,
A program that samples and records a measured value of power consumption of a device at a predetermined period in each of the operation mode, standby mode, and energy-saving mode during which each of the device functions is being executed. There is a program to be implemented in an image forming apparatus having one or more device functions, a standby mode for standby operation, and an energy saving mode,
In each of the operation-specific mode, standby mode, and energy-saving mode each executing the device function, the measured value of the power consumption of the device is sampled and recorded at a predetermined period,
A program for generating statistical information in a predetermined form based on the recorded sampling value and outputting the statistical information.   A storage medium storing the program according to claim 11 or 12.