JP2017021112A - Image formation apparatus, power control method and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To inexpensively provide an image formation apparatus which stably operates even in a state where power source voltage drop frequently occurs by reducing the use frequency of a power storage device.SOLUTION: An image formation apparatus includes: a capacitor 50 which is charged with a rectification power from an external power source 60 and outputs a first DC power; a switching circuit 140 which outputs any of the rectification power and first DC power as a second DC power; a fixing heater 44a which is driven with the second DC power; a voltage detection circuit 154 which detects the voltage value of the rectification power; storage means 111 which stores the rectification voltage value at which the own device erroneously operates as a voltage threshold; and an input/output control unit 110 which outputs a voltage drop amount prediction value by predicting a voltage drop amount related to the driving of the fixing heater 44a at the next and subsequent times on the basis of the voltage difference of the rectification voltage value related to the stop and the driving of the fixing heater 44a and sets the result value obtained by adding the voltage drop amount prediction value to the voltage threshold acquired from the storage means 111 in the storage means 111 as the voltage threshold at which the own device erroneously operates.SELECTED DRAWING: Figure 2

Description

  The present invention relates to a technique suitable for introduction in an environment where a power supply voltage is unstable.

  In recent years, image forming apparatuses have also been installed in countries and regions where the power supply voltage environment is unstable. The image forming apparatus has a product specification value of an operation guarantee range of the input power supply voltage. However, in the above-described countries and regions, the image forming apparatus is used even in a power supply voltage environment that is significantly lower than the guaranteed range. For this reason, there is a problem caused by a decrease in input voltage, and various techniques have been proposed to solve this problem.

  Patent Document 1 discloses a chargeable / dischargeable power storage device that is charged by electric power supplied from an external power source in order to stably operate the image forming apparatus even when the voltage supplied from the external power source decreases. A configuration is disclosed in which, when the voltage supplied from the commercial power supply is lowered, the operation of the image forming apparatus is continued by receiving power supply from the power storage device.

Here, for the purpose of stable operation, an uninterruptible power supply (UPS) is installed in the image forming apparatus, and the threshold for switching the power input to the image forming apparatus from the external power supply to the UPS is set higher. . As a result, when the power supply voltage drops even a little, the power from the UPS is supplied and the image forming apparatus can be operated stably.
However, if the threshold value of the UPS is set high in this way, the number of times the UPS is used increases, the degree of consumption of the storage battery provided in the UPS increases, and the replacement of the storage battery becomes frequent. There was a problem such as.
Further, even in the technique described in Patent Document 1, if the number of times the power storage device is used is large, the degree of consumption of the internal storage battery increases and the use cost increases.

  The present invention has been made in view of the above, and an object thereof is to reduce the number of uses of the power storage device and to provide an image forming apparatus that operates stably even when used in a state where the power supply voltage is frequently lowered at low cost. It is to provide.

  In order to solve the above-mentioned problem, the invention according to claim 1 is characterized in that: Switching means for inputting rectified power and the first DC power and outputting either one as second DC power, a DC load driven by the second DC power, and detecting a voltage value of the rectified power A voltage detection unit that outputs a rectified voltage value, a storage unit that stores a rectified voltage value at which the device itself malfunctions as a voltage threshold value, and the rectified voltage value related to when the DC load is stopped. Predicting means for predicting a voltage drop amount at the time of driving the DC load from the next time onward based on a voltage difference from the rectified voltage value at the time of driving the DC load, and outputting the predicted value as a voltage drop amount prediction value; Voltage threshold setting means for adding the predicted value of the voltage drop to the voltage threshold acquired from the storage means and setting the result value in the storage means as a voltage threshold at which the device itself malfunctions. .

  According to the present invention, it is possible to provide an image forming apparatus that can stably operate even when used in a state where the power supply voltage is frequently reduced and the power supply voltage is frequently reduced, at a low cost.

1 is a cross-sectional view illustrating a schematic mechanism configuration of an image forming apparatus according to an embodiment of the present invention. 2 is a block diagram showing a power supply switching control system of the image forming apparatus. FIG. 4 is a flowchart showing power supply switching processing of the image forming apparatus. It is a flowchart which shows the 1st threshold value change process in the same power supply switching process. It is a flowchart which shows the 1st threshold value change process in the same power supply switching process. It is a flowchart which shows the 2nd threshold value change process in the same power supply switching process. The voltage state by the same power supply switching is shown, (a) is a graph showing a state in which the amount of power supply voltage drop is large due to lighting of the fixing heater, (b) is a graph showing the state when the embodiment is applied, (C) is a graph which shows the state at the time of applying embodiment. (A) and (b) are diagrams showing an example of threshold values depending on the operation mode of the image forming apparatus and the presence or absence of options. BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a diagram for explaining the background of the present invention, in which (a) is a table showing the state of a power supply voltage in an area where the power supply state is bad, and (b) and (c) are graphs showing a lowered state of the power supply voltage. .

Hereinafter, the present invention will be described in detail with reference to embodiments shown in the drawings.
The present invention includes the following configuration in order to provide an image forming apparatus that operates stably even at a low cost by reducing the number of times the power storage device is used and when the power supply voltage is frequently lowered.
That is, the image forming apparatus of the present invention charges the rectified power obtained by rectifying and smoothing the AC power supplied from the external power supply, and outputs the first DC power, the storage unit that outputs the first DC power, the rectified power, and the first DC Switching means for inputting power and outputting either one as second DC power, DC load driven by second DC power, and voltage detection means for detecting voltage value of rectified power and outputting rectified voltage value A storage means for storing a rectified voltage value at which the apparatus itself malfunctions as a voltage threshold, and a rectified voltage value when the DC load is stopped and a rectified voltage value when the DC load is driven. Based on the voltage difference, the voltage drop amount is predicted when the DC load is driven from the next time onward, and the voltage drop amount predicted value is added to the voltage threshold obtained from the storage means, the prediction means outputting the voltage drop amount prediction value, and the storage means. To, characterized in that it comprises a voltage threshold setting means for setting in the storage means result value as a voltage threshold device itself to malfunction, the.
With the above configuration, the number of times the power storage device is used can be reduced, and an image forming apparatus that operates stably even when used in a state where the power supply voltage is frequently lowered can be provided at low cost.

Here, the background of the present invention will be further described.
FIG. 9 explains the background of the present invention, (a) is a table showing the state of the power supply voltage in an area where the power supply state is bad, and (b) and (c) are graphs showing the lowered state of the power supply voltage. FIG.
In general, even in an area where the power supply voltage is 220 VAC, for example, as shown in FIG. 9A, the power supply situation is bad and the voltage fluctuation is large in the time zone such as morning or evening, and the voltage drops to 180 VAC or 150 VAC. Sometimes.
In the example shown in FIG. 9A, the vertical axis represents power supply voltage and the horizontal axis represents time. Thus, even if the voltage is measured at the same place, the fluctuation of the voltage of the day is large, such as a minimum of 155V to a maximum of 230V.

The graph shown in FIG. 9B shows a case where the wiring impedance is normal and the voltage drop due to lighting of the fixing heater provided in the image forming apparatus is small.
Here, the wiring impedance is a resistance generated in the extension cord or power cord from the outlet to the image forming apparatus, and varies depending on the length or thickness of the extension cord or power cord.
In this example, the fixing heater is lit when the daytime power supply voltage is about 220V. Usually, the amount of voltage drop due to lighting of the fixing heater is 10 V or less at the maximum. The halogen heater used as a fixing heater has a small resistance value in the cold state when it is turned off, and a large current flows immediately after the start of lighting, resulting in a large voltage drop. It has a temperature characteristic that current is reduced and stabilized.
The image forming apparatus is an example when the standby mode is set and a voltage that may cause a malfunction is 135V. In the daytime, when the voltage drops at the start of lighting the heater, the voltage is 210 V, and a power supply voltage of 135 V or more is secured. Therefore, the image forming apparatus operates only by supplying power from the external power supply. In the evening, the voltage drops to about 155V, but the voltage drops below 145V even at the start of heater lighting, so it does not fall below the threshold of 135V.

FIG. 9C shows an example in which the voltage fluctuation is large and the wiring impedance is also increased due to so-called “tako-foot wiring”.
In this example, a voltage drop due to lighting of the fixing heater is also increased. As shown in FIG. 9C, when the heater is turned on when the power supply voltage in the daytime is about 220V, the voltage drop may be up to 40V. Also in this case, the fixing heater is a halogen heater, and the power consumption varies.
Here, the image forming apparatus is in the standby mode, and the voltage with a possibility of malfunction is set to 135V. In the daytime, the power supply voltage is 180 V when the fixing heater is turned on, and the electric voltage is secured to be 135 V or more. Therefore, the image forming apparatus operates only by supplying power from the external power source.
However, in the evening, the power supply voltage drops to about 155V, and when the fixing heater is turned on, a further voltage drop of 40V occurs and drops to about 115V. Since this voltage drop occurs in a short time, the power supply from the uninterruptible power supply cannot be switched in time, and the power supply goes down at this moment.
As described above, this is the background of the present invention.

First, a schematic configuration of an image forming apparatus according to an embodiment of the present invention will be described.
FIG. 1 is a cross-sectional view showing a schematic mechanism configuration of an image forming apparatus according to an embodiment of the present invention.
The image forming apparatus 1 is a digital multi-function peripheral using an electrophotographic image forming process, and has a copying function, a printer function, a facsimile function, and the like.
A copy function, a printer function, and a facsimile function can be sequentially switched and selected by an application switching key provided in the operation unit. The copy mode is selected when the copy function is selected, the printer mode is selected when the printer function is selected, and the facsimile mode is selected when the facsimile mode is selected.

The image forming apparatus 1 includes an automatic document feeder (ADF) 10, an image reading device 20, a writing unit 30, an image forming unit 40 that is an image forming unit, and a capacitor 50 that is a power storage unit.
The automatic document feeder 10 conveys documents one by one from the arranged document bundle to the image reading device 20. The image reading device 20 optically reads a document conveyed from the automatic document conveying device 10 and outputs image information. The writing unit 30 outputs writing light to the image forming unit 40 based on the image information from the image reading device 20. The image forming unit 40 includes a photosensitive drum 41, a developing device 42, a conveyor belt 43, and a fixing device 44. Capacitor 50 constitutes a power storage means. The fixing device 44 is provided with a fixing heater 44a which is a heating means composed of a halogen heater.

  The image forming apparatus 1 is driven by being supplied with electric power from an external power source 60 that is a commercial power source. The capacitor 50 is charged with power from the external power source 60. The drive power supply of the image forming apparatus 1 is switched according to the operation state of the image forming apparatus 1, and the power charged in the capacitor 50 is supplied to the image forming apparatus 1 instead of the external power supply 60.

In the copy mode, the image forming apparatus 1 sequentially conveys the original from the original bundle by the automatic original conveying apparatus 10 to the image reading apparatus 20 and reads the image information. Then, the read image information is converted into optical information by the writing unit 30 via the image processing means, and irradiated to the photosensitive drum 41 of the image forming unit 40 as writing light.
The photosensitive drum 41 is uniformly charged by a charger and then exposed to writing light from the writing unit 30 to form an electrostatic latent image. The electrostatic latent image on the photosensitive drum 41 is developed by the developing device 42 to become a toner image. This toner image is transferred onto the transfer paper by the conveying belt 43, and the toner image is fixed on the transfer paper by the fixing device 44 and discharged.

  Although FIG. 1 shows a monochrome type image forming apparatus 1 in which only one photosensitive drum 41 is arranged, the photosensitive drum 41 forms a toner image of yellow, magenta, cyan, black, or the like. It is also possible to use a color image forming apparatus that superimposes each color and transfers it onto a transfer sheet.

Next, a control system for switching power in the image forming apparatus 1 according to the present embodiment will be described.
FIG. 2 is a block diagram showing a power supply switching control system of the image forming apparatus. In this example, the DC load is a fixing heater arranged in the fixing device.
In this embodiment, the image forming apparatus 1 includes an input / output control unit 110, a rectifying / smoothing circuit 120 that is a rectifying / smoothing unit, a charging control circuit 130, a switching circuit 140, and a power supply device 150 in addition to the capacitor 50.
The input / output control unit 110 controls the charging control circuit 130 and the switching circuit 140.
The rectifying / smoothing circuit 120 rectifies and smoothes the alternating current from the external power supply 60 to generate direct-current power. The rectifying / smoothing circuit 120 includes, for example, a diode bridge and an electrolytic capacitor.
The charge control circuit 130 charges the capacitor 50 with DC power supplied from the rectifying and smoothing circuit 120 under the control of the input / output control unit 110. The power of the capacitor 50 is input to the switching circuit 140 as the first DC power.

The switching circuit 140 receives the DC power from the rectifying / smoothing circuit 120 or the first DC power from the capacitor 50 under the control of the input / output control unit 110, and either one of the power is supplied to the power supply apparatus 150 as the second DC power. Output.
The power supply apparatus 150 includes a 24V generation circuit 151 that generates a third DC current, a 5V generation circuit 152, a heater control circuit 153, and a voltage detection circuit 154 as DC power conversion means.
The 24V generation circuit 151 supplies 24V DC power to a 24V load 161 such as a DC motor.
The 5V generation circuit 152 supplies 5V DC power to a 5V load 162 such as a control element.
The heater control circuit 153 supplies power to the fixing heater 44 a of the fixing device 44. The voltage detection circuit 154 detects the voltage value of the rectified power from the rectifying and smoothing circuit 120 and outputs the rectified voltage value.

The input / output control unit 110 is configured as a computer including a CPU (Central Processing Unit), a ROM (Read Only Memory), and a RAM (Random Access Memory). The input / output control unit 110 functions as various control units by executing a program with the CPU. Further, the input / output control unit 110 includes a storage unit 111 that receives a rectified voltage value from the voltage detection circuit 154 in a part of the RAM and stores a rectified voltage value at which the device itself malfunctions as a threshold value that is a voltage threshold value.
Further, the input / output control unit 110 predicts the voltage drop amount at the time of driving the DC load from the next time onward based on the voltage difference between the rectified voltage value at the time of stopping the fixing heater and the rectified voltage value at the time of driving the DC load. Then, it functions as a predicting means that outputs the voltage drop amount predicted value.
Further, the input / output control unit 110 functions as a voltage threshold setting unit that adds the predicted voltage drop amount to the threshold acquired from the storage unit 111 and sets the result value in the storage unit 111 as a threshold at which the apparatus itself malfunctions. .

Next, the operation of the image forming apparatus 1 will be described.
FIG. 3 is a flowchart showing power supply switching processing of the image forming apparatus.
FIG. 3 shows main control processing of the image forming apparatus 1. The storage means 111 of the input / output control unit 110 includes “power supply voltage immediately after heater on (1)”, “power supply voltage immediately after heater on (2)”, “power supply voltage after heater on stable (3)”, “difference (4 ) ”And“ Difference (5) ”are stored.
First, the input / output control unit 110 detects a power supply voltage (step S1).
Next, the input / output control unit 110 performs a first threshold value changing process (step S2), and further determines whether or not the detected power supply pressure value is equal to or less than the threshold value (step S3). When the power supply voltage is equal to or lower than the threshold value (step S3, Yes), the input / output control unit 110 switches the switching circuit 140 and supplies power from the capacitor 50 (step S4).

Further, the input / output control unit 110 detects the power supply voltage (step S5), and then the input / output control unit 110 performs the second threshold value changing process (step S6), and the detected power supply pressure value is equal to or greater than the threshold value. It is determined whether or not (step S7).
When the power supply voltage is equal to or higher than the threshold value (step S7, Yes), the input / output control unit 110 switches the switching circuit 140 and supplies power from the external power supply 60 (step S8).
The input / output control unit 110 repeats the processing from step S1 to step S8. Since it is unknown when the power supply voltage fluctuates, the threshold value changing process is always performed. This threshold value changing process is performed, for example, at a cycle of 100 ms.

Next, the first threshold value changing process will be described.
4 and 5 are flowcharts showing the first threshold value changing process in the power source switching process, and FIGS. 8A and 8B are diagrams showing an example of the threshold value depending on the operation mode of the image forming apparatus and the presence / absence of options.
In the first threshold value changing process, the input / output control unit 110 first sets an initial threshold value based on the setting mode of the image forming apparatus 1 and the presence / absence of peripheral devices.
The initial threshold values are shown in the table of FIG. The initial thresholds are determined to be “140V”, “160V”, “165V”, and “135V” depending on the operation modes “energy saving return”, “printing”, and “standby” and the presence or absence of peripheral devices such as a paper bank. The input / output control unit 110 sets a threshold value corresponding to the operation mode in the storage unit 111 (step S11).

Next, the input / output control unit 110 determines whether or not the fixing heater 44a is currently in an off state and next the fixing heater 44a is scheduled to be in an on state (step S12).
When the fixing heater 44a is currently in the OFF state and the fixing heater 44a is not scheduled to be turned on next, the input / output control unit 110 stores the measured data in “Power supply voltage (2) immediately after the heater is turned on” in the storage unit 111. It is determined whether or not there is (step S13).
When actual measurement data is not stored in the “power supply voltage (2) immediately after heater on” (No in step S13) in the storage unit 111, the input / output control unit 110 reads “power supply voltage (1) when heater is off” in the storage unit 111. The current power supply voltage is set in the buffer (step S14).
Next, the input / output control unit 110 sets 220 V in the buffer of “power supply voltage (2) immediately after the heater is turned on” in the storage unit 111 (step S15).
Furthermore, the input / output control unit 110
Threshold = “initial threshold” + “power supply voltage when heater is turned off (1)” − “power supply voltage immediately after heater is turned on (2)”
And the threshold value is set in the storage means 111 (step S16), and the first threshold value changing process is terminated.

On the other hand, when the measured data is stored in the “power supply voltage immediately after the heater is turned on (2)” of the storage unit 111 (step S13, Yes), the input / output control unit 110 has a power supply voltage within a guaranteed range (for example, 276V to 187V). It is determined whether or not there is (step S17).
When the power supply voltage is within the guaranteed range (step S17, Yes), the input / output control unit 110 updates the threshold value with the current power supply voltage setting in the “power supply voltage when heater is off (1)” buffer (step S18). Furthermore, the input / output control unit 110 sets the threshold value as “threshold value =“ initial threshold value ”+ difference (4)” and updates the threshold value (step S19).
When the power supply voltage is not within the guaranteed range (step S17, No), the input / output control unit 110 executes step S19 and ends.

On the other hand, when the fixing heater 44a is currently on or when there is no plan to turn on the heater next (step S12, No), the input / output control unit 110 determines whether or not the fixing heater 44a has just been turned on (step S12). Step S20).
When the fixing heater 44a is immediately after lighting (step S20, Yes), the input / output control unit 110 determines whether or not the power supply voltage is within a guaranteed range (for example, 276V to 187V) (step S21).
When the power supply voltage is within the guaranteed range (step S21, Yes), the input / output control unit 110 sets the current power supply voltage in the buffer of “power supply voltage when heater is off (2)” (step S22).
Furthermore, the input / output control unit 110
Difference (4) = “Power supply voltage when heater is off (1)” − “Power supply voltage immediately after heater is on (2)”
And the difference (4) value is updated as a threshold value (step S23), and the first threshold value changing process is terminated.

When the fixing heater 44a is not immediately after lighting (step S20, No), the input / output control unit 110 determines whether or not the fixing heater 44a is in a stable period after the heater is lit (more than 200 ms has elapsed since the heater was turned on) (step S24). ).
When the fixing heater 44a is in a stable period (step S24, Yes), the input / output control unit 110 determines whether or not the power supply voltage is within an operation guarantee range (for example, 276V to 187V) (step S25).
When the power supply voltage is within the operation guarantee range (step S25, Yes), the input / output control unit 110 sets the current power supply voltage in the buffer of “power supply voltage at heater off (3)” (step S26).
Furthermore, the input / output control unit 110
Difference (5) = “Power supply voltage when heater is off (1)” − “Power supply voltage immediately after heater is on (3)”
And the difference (5) value is updated as a threshold value (step S27), and the first threshold value changing process is terminated.

If it is not the stable period immediately after the heater is turned on (No in step S24), the input / output control unit 110 determines whether or not the fixing heater 44a is currently in the off state and the fixing heater 44a is scheduled to be in the off state next time. (Step S28).
If the fixing heater 44a is currently in the off state and the fixing heater 44a is scheduled to be in the off state (step S28, Yes), the input / output control unit 110 sets the threshold value of the input / output control unit 110 to threshold = “initial”. Is updated (step S29), and the first threshold value changing process is terminated.
If the fixing heater 44a is not currently in the off state, or if the fixing heater 44a is not scheduled to be in the off state (step S28, No), the first threshold value changing process is terminated.

Next, the second threshold value changing process will be described.
FIG. 6 is a flowchart showing a second threshold value changing process in the power source switching process.
In the second threshold value changing process, the input / output control unit 110 sets an initial threshold value based on the setting mode of the image forming apparatus 1 and the presence / absence of peripheral devices based on FIG. 8A (step S31).
Next, the input / output control unit 110 determines whether or not the fixing heater 44a is in a stable period after the heater is turned on (elapse of 200 ms or more after the heater is turned on) (step S32).
When the fixing heater 44a is in a stable period (step S32, Yes), the input / output control unit 110
Threshold = “initial threshold” + “difference (5)”
And the threshold value is stored in the storage unit 111 and updated (step S33), and the second threshold value changing process is terminated.
On the other hand, if the fixing heater 44a is not in the stable period (No in step S32), the input / output control unit 110 determines whether or not the fixing heater 44a is currently in an off state and is scheduled to be turned off again (step). S34).
When the fixing heater 44a is currently in the off state and is scheduled to be turned off again (Yes in step S34), the input / output control unit 110 updates the threshold value of the storage unit 111 as threshold = “initial threshold value”. (Step S34), the second threshold value changing process is terminated.
On the other hand, if the fixing heater 44a is not currently in an off state or is not scheduled to be turned off again (No in step S34), the input / output control unit 110 ends the second threshold value changing process as it is.

Next, an example of the operation by the image forming apparatus 1 will be described.
FIG. 7 shows a voltage state by the power source switching process, (a) is a graph showing a state in which the amount of power supply voltage drop is large by turning on the fixing heater, and (b) is a case where the embodiment is applied. The graph which shows the state of (1), (c) is a graph which shows the state at the time of applying embodiment. The examples shown in FIGS. 7A, 7B, and 7C are examples in which voltage fluctuation is large and wiring impedance is large.

FIG. 7A shows an example when the fixing heater is turned on when the power supply voltage is about 220V. Note that, when the temperature of the fixing device 44 becomes equal to or lower than the specified value, the image forming apparatus 1 controls to turn on the fixing heater 44a as necessary to maintain the temperature of the fixing device 44.
In this example, the wiring impedance is large, and the amount of voltage drop may be up to 40V. In the image forming apparatus 1, the power supply voltage values immediately before and after the lighting of the fixing heater 44 a are stored in the storage unit 111 of the input / output control unit 110 according to the flowcharts shown in FIGS. 3, 4, and 5. The difference is added to the initial threshold.
In FIG. 7A, immediately before the first fixing heater 44a is turned on, the threshold value is not changed because there is no storage data of the voltage value immediately after the fixing heater 44a is turned on. Note that, as a configuration as shipped from the factory, the stored data may have a default value.
Immediately after the start of lighting of the second fixing heater 44a in FIG. 7A, the threshold value is changed from 135V to 175V as shown by the broken line.
However, since the power supply voltage value is 220V (when the fixing heater 44a is not lit), a power supply voltage of 175V or more is secured, and the image forming apparatus operates only by supplying power from an external power supply.

In the example shown in FIG. 7B, the threshold value is changed to 175 V in the daytime, just before the lighting of the fixing heater 44a, in consideration of the voltage drop due to the lighting of the fixing heater 44a.
However, since the power supply voltage is secured at 220 V, the image forming apparatus operates only by supplying power from the external power supply.
In the evening, the voltage drops to about 155V. Immediately before the start of lighting of the fixing heater 44a, the previously stored voltage value immediately before and after the start of lighting of the heater is added to the threshold value. This threshold value has changed from 135V to 175V, and the current power supply voltage 155V is lower than this. For this reason, immediately before the heater lighting is started, the input / output control unit 110 controls the switching circuit 140 to switch to the power supply from the capacitor 50.
After the switching, when the fixing heater 44a is turned on, the power is supplied from the capacitor 50, so that the power supply voltage does not drop and remains at 155V. Thereafter, in a period in which the inrush current is large immediately after the lighting of the fixing heater 44a is large, the power supply from the capacitor 50 is continued. During the stable period when the fixing heater 44a is lit, the threshold value is returned to the initial value again to make a determination. Since the threshold value is 135V and the current power supply voltage 155V exceeds the threshold value, the input / output control unit 110 controls the switching circuit 140 to switch to power supply from an external power supply.
In this embodiment, by controlling in this way, it is possible to prevent power interruption due to inrush current at the start of lighting of the fixing heater 44a, and to achieve stable operation of the image forming apparatus. In addition, by using the power from the capacitor 50 in this manner, the use timing of the capacitor 50 can be optimized, and the effect of reducing the number of times of use of the capacitor 50 and extending the life can also be obtained.

  FIG. 7C is an example of voltage values and threshold values that cause malfunction during printing. An example when the threshold is set to 165V is shown. When the voltage of the external power supply 60 falls below 165 V in the evening, the input / output control unit 110 controls the switching circuit 140 to switch to the power supply from the capacitor 50.

Next, a specific example of power supply switching will be described.
The first example is a case where the image forming apparatus 1 is activated. The power supply voltage value is the rated voltage of 220V. Further, in this example, after the main power supply of the image forming apparatus 1 is turned on, the voltage measurement results when the fixing heater 44a is turned off and when it is turned on have never been obtained.
First, the input / output control unit 110 acquires the voltage of the external power supply 60 (step S1), and performs a first threshold value changing process (step S2). In the first threshold value changing process, the input / output control unit 110 first sets a threshold value according to the operation mode of the image forming apparatus 1 (step S11). In this example, the threshold set in step S11 is set according to the table shown in FIG.
In this case, the input / output control unit 110 sets 140V as the initial threshold value as “energy saving return”.
Next, the input / output control unit 110 determines the state of the fixing heater 44a and then whether or not the fixing heater 44a is turned on (step S12). Immediately after the image forming apparatus 1 is activated, the fixing heater 44a is in an off state, and thus the threshold value remains 140V (No in step S12).
Therefore, the process returns from the first threshold change process to the main control process (FIG. 3). In the main control process, since the detected power supply voltage value is 220V and the threshold value is 140V, the input / output control unit 110 determines “No” in step S3.
When the fixing heater 44a is switched from the OFF state to the next scheduled ON state, the determination in step S12 in the first threshold value changing process is “Yes”, and the data is stored in the buffer of “power supply voltage (2) immediately after heater ON”. It is confirmed whether it has been done (step S13). The buffer data disappears when the main power is turned off. This condition is adopted because the installation environment (such as the position of the outlet) of the image forming apparatus 1 may be changed when the main power supply is turned off. Further, since the installation environment does not change until the main power source is switched from the on state to the off state, it is appropriate to use the data if it is stored in the buffer.

In step S13, the input / output control unit 110 determines “No” because the value of “power supply voltage (2) immediately after heater ON” is empty from the beginning. The input / output control unit 110 sets the current voltage 220V to “power supply voltage (1) when the heater is turned off” (step S14), and the rated voltage value 220V (measurement) to “power supply voltage (2) immediately after the heater is turned on”. (Not data). For this reason, the threshold value is as follows at this stage (step S16).
Threshold = 140V + 220V−220V = 140V
By obtaining the threshold value in this way, immediately after the main power source is turned on, the first heater lighting is always performed by supplying from the external power source.
Returning to the main control process again, the input / output control unit 110 determines “Yes” in step S7 because threshold value 140V <power supply voltage 220V, and continues power supply from the external power supply (step S8).

  Next, after the fixing heater 44a is turned on, if the input / output control unit 110 determines “Yes” in step S20 of the first threshold value changing process, next, whether or not the power supply voltage is within the operation guaranteed range of 278V to 187V. Is determined (step S21). This determination is made because the amount of voltage drop when the fixing heater 44a is turned on is larger when the power supply voltage value is higher. Measurement is performed under an unfavorable condition with a large voltage drop, and the voltage value immediately after the fixing heater 44a is turned on is obtained as measurement data.

If the input / output control unit 110 determines “No” in step S13, in step S22, the input / output control unit 110 sets the current voltage in the buffer of “power supply voltage (2) immediately after heater ON”. As an example, the power supply voltage value is 180V. In step S23, 220V−180V = 40V is stored as “difference (4)”.
Thereafter, when the fixing heater 44a enters a stable period after lighting, the input / output control unit 110 determines “Yes” in step S24. Then, the process proceeds to step S26 and step S27. At this time, the power supply voltage value of “the power supply voltage after the heater ON is stabilized (3)” is 210 V as an example.
In this manner, the input / output control unit 110 stores in the storage unit 111 “power supply voltage immediately after heater on (1)”, “power supply voltage immediately after heater on (2)”, “power supply voltage after heater on stable (3)”, “Difference (4)” and “Difference (5)” are stored in the buffer. The input / output control unit 110 switches to power supply from the capacitor 50 in consideration of the voltage drop amount of the fixing heater 44a immediately before the next lighting of the fixing heater 44a based on the obtained values. It is determined whether or not to continue supplying power from the external power source 60.

  In the above description of the first threshold value update process, it is assumed that the fixing heater 44a is lit unconditionally for the first lighting of the fixing heater 44a. However, immediately before the first lighting, it is detected whether or not the power supply voltage is within the guaranteed operating range, and if it is within the range, the processing is continued as it is, and if it is out of range, “Wait processing” is inserted until it settles within the range. Alternatively, a message indicating that the power supply voltage is out of the operation guaranteed range may be displayed on the operation screen, so that it is not necessary to shift unconditionally. If the power supply voltage is outside the guaranteed operating range, the power supply from the capacitor 50 may be switched to wait until the power supply voltage falls within the guaranteed range.

Next, a case where the power supply voltage is reduced from 220V to 155V will be described as a second example.
The operation mode of the image forming apparatus 1 is “standby”.
As shown in FIG. 4, an initial threshold value = 135 V is set as the standby threshold value. During the standby, the fixing heater 44a is initially in an off state, and the threshold value is 135V. Since the power supply voltage value is 155V, the input / output control unit 110 determines “No” in step S28, the threshold value remains 135V, ends the first threshold value changing process, and returns to the main control process.
In the main control process, since the detected power supply voltage value is 155V and the threshold value is 135V, the input / output control unit 110 determines “No” in step S3. When the fixing heater 44a is switched from the OFF state to the next scheduled fixing heater 44a, the input / output control unit 110 determines “Yes” in step S12 in the first threshold processing.
Then, the input / output control unit 110 checks whether or not data is stored in the buffer of “power supply voltage (2) immediately after heater ON” (step S13). In this case, since the input / output control unit 110 stores data when the fixing heater 44a is turned on for the first time, it determines “Yes”. Further, the input / output control unit 110 sets the current voltage 155 V to “power supply voltage (1) when the heater is OFF” (step S18), and further calculates the threshold value in step S19 as follows.
Threshold = 135V + 40V = 175V

  Returning to the main control process again, since the threshold value 175 V <the power supply voltage 155 V, the input / output control unit 110 determines “No” in step S <b> 3 and switches to the power supply from the capacitor 50. In order to switch to the power supply from the capacitor 50, the input / output control unit 110 determines “Yes” in step S3.

After the fixing heater 44a is actually turned on, the input / output control unit 110 performs the determination in step S32 in the second threshold value changing process. If the fixing heater 44a is in a stable period after lighting, the input / output control unit 110 determines “Yes” and updates the threshold value as follows (step S33).
Threshold = 135V + 10V = 145V

Returning to the main control process again, since the threshold value 145V <power supply voltage 155V, the input / output control unit 110 determines “Yes” in step S7 and switches to power supply from the external power supply 60 (step S8). By controlling in this way, it is possible to supply power from the storage battery only to the minimum necessary portion when the fixing heater 44a is started.
As a result, the number of times the capacitor 50 is used can be reduced, and stable operation of the image forming apparatus 1 can be realized at a low cost even in an area where the power supply environment is bad.

In the above-described embodiment, if the power supply voltage is within the operation guarantee range, the power supply voltage value immediately after the fixing heater 44a is turned on is updated every time to improve the accuracy.
However, the measurement of the power supply voltage value immediately after the fixing heater 44a is turned on is performed only once, and the voltage drop amount for each power supply voltage value can be obtained by simulation using the measurement result of this one time. The same applies to the voltage drop amount during the stable period of the fixing heater 44a.

<Configuration, operation and effect of exemplary embodiment of the present invention>
<First aspect>
The image forming apparatus of this aspect is charged with the rectified power obtained by rectifying and smoothing the AC power supplied from the external power supply 60, the capacitor 50 outputting the first DC power, the rectified power and the first DC power. Is input, and one of them is output as the second DC power, the fixing heater 44a driven by the second DC power, and the voltage detection that detects the voltage value of the rectified power and outputs the rectified voltage value An image forming apparatus 1 including a circuit 154, a storage unit 111 that stores a rectified voltage value at which the apparatus itself malfunctions as a threshold, a rectified voltage value when the fixing heater 44a is stopped, and a driving time of the fixing heater 44a. Based on the voltage difference from the rectified voltage value, a prediction unit and a storage unit 1 that predict a voltage drop amount when the DC load is driven next time and output it as a voltage drop amount prediction value. And an input / output control unit 110 as a voltage threshold setting unit that adds the predicted value of the voltage drop to the threshold acquired from 1 and sets the result value in the storage unit 111 as a threshold at which the device itself malfunctions. To do.
According to this aspect, the threshold at which the apparatus malfunctions is predicted based on the voltage difference between the rectified voltage value when the fixing heater 44a is stopped and the rectified voltage value when the fixing heater 44a is driven, and stored in the storage unit 111. The power supply of the capacitor 50 and the external power supply 60 is switched based on this threshold value. For this reason, it is possible to provide the image forming apparatus 1 that operates stably even if the capacitor 50 is used in a state where the number of times of use of the capacitor 50 is reduced and the power supply voltage is frequently lowered.

<Second aspect>
In this aspect, the voltage detection circuit 154 detects the rectified voltage value when the fixing heater 44a is stopped and the rectified voltage value when the fixing heater 44a is driven. It is when it is in the voltage range.
According to this aspect, the voltage drop amount can be measured based on a large voltage drop amount when the fixing heater 44a is turned on with a high voltage value. For this reason, a threshold value with a margin can be set.

<Third aspect>
This mode includes a storage unit 111 that stores in advance a voltage difference between a rectified voltage value related to when the fixing heater 44a is stopped and a rectified voltage value related to the start of driving of the fixing heater 44a, and an input / output control unit that is a voltage threshold setting unit 110 is a voltage difference storage means during a period in which the voltage detection circuit 154 has not acquired the rectified voltage value related to the stop of the DC load and the rectified voltage value related to the start of driving of the DC load after starting up the apparatus. The voltage difference acquired from the above is added to the threshold value.
According to this aspect, the voltage detection circuit 154 does not acquire the rectified voltage value related to the stop of the DC load and the rectified voltage value related to the start of driving of the DC load after starting the own device. The voltage difference acquired from the difference storage means is added to the threshold value. Therefore, immediately after the image forming apparatus 1 is activated, the first fixing heater 44a can be turned on from the external power source 60, and the image forming apparatus 1 can be operated reliably.

<4th aspect>
In this embodiment, the 24V generation circuit 151 and the 5V generation circuit 152 that convert the second DC power output from the switching circuit 140 into the third DC power, and the 24V load 161 that consumes the power supplied from these or the external power supply 60 are used. The input / output control unit 110, which is a voltage threshold value setting means, increases the threshold value in each operation mode as the load amount of the DC load increases. It is characterized by setting.
According to this aspect, the input / output control unit 110 sets the voltage site according to the operation mode of the image forming apparatus 1. Therefore, it is possible to set a threshold value suitable for the operation mode of the image forming apparatus 1.

<5th aspect>
This aspect is characterized by including a fixing heater 44a.
According to this aspect, the fixing heater 44a is provided. Therefore, the threshold value can be set in the image forming apparatus 1 in which the fixing device 44 includes the fixing heater 44a.

<Sixth aspect>
This aspect is characterized by using a capacitor 50.
According to this aspect, electric power can be stored in the capacitor 50, and electric power can be supplied to the fixing heater 44a by switching to the external power source 60. For this reason, a large amount of electric power can be supplied, and quick charging can be performed.

<Seventh aspect>
The power control method according to this aspect charges the rectified power obtained by rectifying and smoothing the AC power supplied from the external power supply 60, outputs the first DC power, the rectified power and the first DC power. Switching circuit 140 that outputs one of them as second DC power, a fixing heater 44a that is driven using the second DC power, and a voltage that detects the voltage value of the rectified power and outputs the rectified voltage value A power control method by the image forming apparatus 1 including the detection circuit 154, the storage step of storing the rectified voltage value at which the apparatus itself malfunctions in the storage unit 111 as a threshold value, and the rectified voltage value related to when the fixing heater 44a is stopped On the basis of the voltage difference between the rectified voltage value at the start of driving of the fixing heater 44a and the rectified voltage value at the start of driving of the fixing heater 44a, Prediction step for outputting as a pressure drop prediction value, and a voltage threshold setting step for adding the voltage drop prediction value to the threshold acquired from the storage means 111 and setting the result value in the storage means 111 as a threshold for malfunction of the device itself And executing.
According to this aspect, the threshold at which the apparatus malfunctions is predicted based on the voltage difference between the rectified voltage value when the fixing heater 44a is stopped and the rectified voltage value when the fixing heater 44a is driven, and stored in the storage unit 111. The power supply of the capacitor 50 and the external power supply 60 is switched based on this threshold value. For this reason, it is possible to provide the image forming apparatus 1 that operates stably even if the capacitor 50 is used in a state where the number of times of use of the capacitor 50 is reduced and the power supply voltage is frequently lowered.

<Eighth aspect>
The program of this aspect is characterized by causing a processor to execute each step in the power control method.
According to this aspect, the processor can execute each step of the power control method. For this reason, it is possible to provide the image forming apparatus 1 that operates stably even if the capacitor 50 is used in a state where the number of times of use of the capacitor 50 is reduced and the power supply voltage is frequently lowered.

DESCRIPTION OF SYMBOLS 1 ... Image forming apparatus, 44 ... Fixing apparatus, 44a ... Fixing heater (DC load), 50 ... Capacitor (electric storage means), 60 ... External power supply, 110 ... Input / output control part (prediction means, voltage threshold setting means), 111 ... Storage means, 120 ... rectifying and smoothing circuit, 140 ... switching circuit

JP 2008-176288 A

Claims (8)

Power storage means for charging rectified power obtained by rectifying and smoothing AC power supplied from an external power supply, and for outputting first DC power;
Switching means for inputting the rectified power and the first DC power and outputting either one as the second DC power;
A DC load driven by the second DC power;
A voltage detection unit that detects a voltage value of the rectified power and outputs a rectified voltage value;
Storage means for storing a rectified voltage value at which the device itself malfunctions as a voltage threshold;
Based on the voltage difference between the rectified voltage value when the DC load is stopped and the rectified voltage value when the DC load is driven, the voltage drop amount is predicted when the DC load is driven from the next time onward. A predicting means for outputting as a predicted amount of descent;
Voltage threshold setting means for adding the voltage drop amount predicted value to the voltage threshold acquired from the storage means, and setting the result value in the storage means as a voltage threshold at which the device itself malfunctions;
An image forming apparatus comprising:   The timing at which the voltage detection means detects the rectified voltage value when the DC load is stopped and the rectified voltage value when the DC load is driven is the voltage at which each rectified voltage value guarantees the operation of the device. The image forming apparatus according to claim 1, wherein the image forming apparatus is in a range. Voltage difference storage means for storing in advance a voltage difference between the rectified voltage value related to the stop of the DC load and the rectified voltage value related to the start of driving of the DC load;
The voltage threshold setting means includes:
The voltage difference storage is performed during a period in which the voltage detection unit has not acquired the rectified voltage value related to the stop of the DC load and the rectified voltage value related to the start of driving of the DC load after starting the own device. The image forming apparatus according to claim 1, wherein the voltage difference acquired from the unit is added to the voltage threshold value. DC power conversion means for converting the second DC power output from the switching means into third DC power;
A DC load that consumes power supplied from the power storage means or the DC power conversion means,
The own device has a plurality of operation modes,
The voltage threshold setting means includes:
4. The image forming apparatus according to claim 1, wherein, in each of the operation modes, the voltage threshold is set to be larger as the load amount of the DC load is larger. 5.   The image forming apparatus according to claim 1, wherein the DC load is a heating unit.   The image forming apparatus according to claim 1, wherein the power storage unit uses a capacitor. Power storage means for charging rectified power obtained by rectifying and smoothing AC power supplied from an external power supply, and for outputting first DC power;
Switching means for inputting the rectified power and the first DC power and outputting either one as the second DC power;
A DC load driven using the second DC power;
A voltage detection unit that detects a voltage value of the rectified power and outputs a rectified voltage value;
A storage step of storing in the storage means a rectified voltage value at which the device itself malfunctions as a voltage threshold;
Based on a voltage difference between the rectified voltage value related to the stop of the DC load and the rectified voltage value related to the start of driving of the DC load, a voltage drop amount related to the start of driving of the DC load after the next time is predicted. A prediction step of outputting as a voltage drop prediction value;
A voltage threshold setting step of adding the voltage drop amount predicted value to the voltage threshold acquired from the storage means, and setting the result value in the storage means as a voltage threshold at which the device itself malfunctions;
The power control method characterized by performing.   The program which makes a processor perform each step in the power control method of Claim 7.

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