JP2003223122A - Light emitting indicator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a light emitting indicator which can indicate whether the current state of a device having a standby mode is an ordinarily usable mode or the energy saved standby mode while keeping satisfactory visibility. <P>SOLUTION: A light emitting indicator 10 packaged on a control panel 3 of an image forming device indicates whether the image forming device is in the use mode for ordinarily using a facsimile part 1 or a printer part 2 or the power consumption reduced standby mode at present by turning on a mode display part 12. In the standby mode, a panel control part 11 makes a quantity of light to be emitted on the mode display part 12 lower than the use mode and performs control such that the mode display part is flickered and turned on in a visible cycle. <P>COPYRIGHT: (C)2003,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention is mounted in various devices such as an image forming device such as a printer or a copying machine, an image input device such as a scanner, or a display device.
By lighting a light emitting element such as an ED (Light Emitting Diode), it is indicated whether at least the device is in a normally usable state (use mode) or in a standby state in which power consumption is suppressed (standby mode). The present invention relates to a light emission indicator.

[0002]

2. Description of the Related Art In recent years, in various devices such as printers, scanner devices, and display devices, energy saving (hereinafter referred to as energy saving) in view of the problem of global warming.
Is strongly demanded. Correspondingly, in many OA devices, instead of maintaining the device in a use mode (ready state) in which the device can be immediately used at all times, when the device is left for a predetermined time in the use mode, A configuration is adopted in which most of the devices are turned off to switch to a standby mode (standby state) in order to save energy. In particular, in the case of an image forming apparatus that employs an electrophotographic method for the image forming unit, the fixing unit is kept at a high temperature at which the toner transferred onto the paper can be heated and pressure-bonded, and is left unused for a long time. That consumes much power.
By setting the standby mode and lowering the temperature of the fixing unit below the temperature required for fixing, power consumption can be effectively reduced.

A device having such an energy saving function is
A light emitting indicator using a light emitting element such as an LED is mounted on the operation panel or the like, and using the light emitting indicator,
At present, it indicates whether the device is in a use mode or a standby mode. In many cases, the light emitting element that indicates the use mode is also used as the power ON element that indicates that the device is powered on.

Regarding an energy saving function using a light emitting element, Japanese Patent Laid-Open No. 2001-265294 discloses a liquid crystal display device capable of switching between a reflective mode and a transmissive mode on an operation panel of an image forming apparatus. Backlight device for illuminating the liquid crystal display device from the back by using
In the above-mentioned use mode, while it is turned on with high brightness, it is normally turned off in the standby mode and is turned on with low brightness only when the surroundings are dark. According to this, the power consumption of the operation panel is reduced by reducing the power used in the operation panel without causing a situation in which the power of the operation panel is cut off in the standby mode and the convenience of the user is impaired. Can be realized.

Further, in Japanese Unexamined Patent Publication No. 10-308987, a sensor for detecting ambient brightness is provided in a wireless remote controller, and a signal is sent according to the ambient brightness detected by the sensor. A configuration for saving energy is described by controlling the output of the light emitting element to be transmitted, that is, by causing the light emitting element to emit light with the minimum energy that the light receiving element can receive and transmitting a signal.

[0006]

As described above, in a device having a standby mode capable of energy saving, whether the mode is a use mode or a standby mode is indicated by turning on a light emitting element in a light emission indicator. It looks like
With such a configuration, the amount of electric power used in the light emission indicator is the same in both the use mode and the standby mode. Therefore, while the problem of global warming is highlighted and further energy saving is required, such a configuration is not sufficient.

Further, the technique disclosed in Japanese Patent Application Laid-Open No. 2001-265294 is not intended for a light emission indicator that emits light from a light emitting element, but for a backlight device that illuminates a liquid crystal display device from the back side. It controls the light emission in the mode. Therefore, in the standby mode, if the surroundings are bright, the light emitting element is completely turned off, which cannot be applied to the light emitting indicator.

Similar to the above, Japanese Patent Laid-Open No. 10-308987
The technology described in the publication is also not intended for a light emitting indicator that emits light from a light emitting element, and the output of the light emitting element of the wireless remote controller is within a range that the light receiving element can detect according to the ambient brightness. It is something to drop. Therefore, in the standby mode, it is conceivable to control the light emitting element output of the light emitting indicator to a value that can be visually recognized according to the brightness of the surroundings of the device, but in the case of human visual recognition, the visibility depends on only the light emitting element output. Therefore, even if it is applied to a light emission indicator, it does not mean that good visibility can be secured and energy saving can be achieved.

The present invention has been made in view of the above problems, and in an apparatus having a standby mode, it is preferable to determine whether the current state of the apparatus is a normally usable use mode or a standby mode. An object of the present invention is to provide a light emission indicator that can be displayed with low power consumption while ensuring visibility.

[0010]

The light emitting indicator of the present invention is
In order to solve the above problems, it is mounted in various devices, and by turning on the light emitting element, at least the device is in a normal use mode or in a standby mode in which power consumption is reduced. A light emission indicator as shown, characterized in that the light emission amount of the light emitting element in the standby mode is lower than that in the use mode, and the light emission control means changes the light emission amount in a visible cycle. There is.

According to this, since the light emission control means reduces the light emission amount of the light emitting element in the standby mode to be lower than the light emission amount in the use mode, the amount of electric power consumed in the light emission indicator in the standby mode is changed to the use mode. It can be kept lower than the amount of electric power at that time. Moreover, the light emission control means does not simply decrease the light emission amount but changes the light emission amount in a visually recognizable cycle. It becomes possible to compensate for the deterioration of sex. Further, the visibility due to the variation of the light emission amount is improved, and the light emission amount in the standby mode can be reduced more effectively.

Therefore, in a device having a standby mode, low power consumption is ensured while ensuring good visibility as to whether the current state of the device is a normally usable use mode or a standby mode. It is possible to provide a light emission indicator that can be shown in.

The fluctuation of the light emission amount by the light emission control means is
It may be changed in a constant cycle or in a random cycle in which the fluctuation cycle is irregular. By changing in a random cycle, the change in the amount of emitted light becomes irregular, and the visibility is further improved.

Further, as the variation of the light emission amount by the light emission control means, the light emitting element may be turned on and off. Also in this case, by making the blinking cycle random, the blinking becomes irregular, and the visibility is further improved.

Further, a plurality of the light emitting elements may be provided, and the light emission control means may alternately and alternately light the plurality of light emitting elements to change the light emission amount.
In this case, since any one of the plurality of light emitting elements is lit, even if the lighting cycle of one element is lengthened, the risk of erroneously recognizing that the light is off is reduced.

In the structure in which the plurality of light emitting elements are alternately turned on, it is more preferable that each emission color of the plurality of light emitting elements includes a combination of at least two colors. Since the color changes in addition to the change in the amount of light emitted,
The visibility is further improved.

Further, the light emission control means may control the light emission amount of the light emitting element by pulse-driving the light emitting element in a non-visible period and controlling the pulse width thereof.

The method of pulse-driving the light emitting element and controlling the pulse width at that time to control the amount of light emission is necessary to obtain the same amount of light emission as compared with the method of controlling the amount of light emission by controlling the amount of current. Since it is possible to reduce the amount of power consumption, it is more preferable in terms of power saving. Further, by controlling the light emission amount by pulse driving, the control for reducing the light emission amount and the control for varying the light emission amount can be performed in an integrated manner, which facilitates the processing.

Further, the above-described light emission indicator of the present invention further comprises brightness detection means for detecting the brightness around the light emission indicator such as a place where the device equipped with the light emission indicator is used. However, the light emission control means may be characterized by controlling the degree of decrease in the light emission amount according to the detection value of the brightness detection means.

According to this, since the light emission control means controls the degree of decrease in the light emission amount according to the detection value of the brightness detection means for detecting the brightness around the light emission indicator, the light emission amount of the light emitting element is controlled. It can be adjusted according to the brightness of the surroundings. In other words, when the surroundings are dark, it is possible to visually recognize even a small amount of light emission. Therefore, when the surroundings are dark, the decrease amount of the amount of light emission is increased. The lower the amount of light emission, the less likely it is to be mistaken for turning off the light. Accordingly, it is possible to more effectively save power without impairing the visibility.

Further, in this case, the light emission control means may further control the degree of change of the visible light emission amount according to the detection value of the brightness detection means.

The brighter the surrounding area, the smaller the amount of decrease in the amount of light emitted from the light emitting element and the higher the power consumption. Therefore, the amount of variation in the amount of light emission is controlled by the amount of light emission that cannot be reduced, and the overall power consumption is reduced. Try to keep it down.

That is, when the light emitting element is turned on and off,
The variation may be adjusted so as to shorten the lighting time.
This makes it possible to save power more effectively without impairing the visibility.

The light emission control means is a CPU (Cent).
ral Processing Unit) or a logic circuit. In the case of a CPU, fine and flexible control of the light emission amount can be easily performed.
In the case of the logic circuit, the power consumption in the standby mode can be suppressed more than that when the CPU is used because the clock-driven CPU is not used.

[0025]

1 is a block diagram showing an embodiment of the present invention.
The following is a description with reference to FIG. Here, a case where the light emission indicator is installed in an image forming apparatus having a facsimile function will be exemplified.

The block diagram of FIG. 2 shows a schematic configuration of an image forming apparatus equipped with the light emission indicator of the present embodiment.

As shown in the figure, the image forming apparatus mainly includes a facsimile section 1, a printer section 2, an operation panel section 3, a main control section 4, a power supply restoration section 5, a main power supply section 6, and a standby sub power supply. It has a section 7.

The facsimile unit 1 is a functional unit that realizes a facsimile function in the image forming apparatus, and the printer unit 2 is a functional unit that realizes a printer function in the image forming apparatus. The operation panel unit 3 is a functional unit used for inputting various operation instructions to the image forming apparatus and providing information from the image forming apparatus. Hereinafter, when the facsimile unit 1, the printer unit 2, and the operation panel unit 3 are collectively handled, they are referred to as functional units 1 to 3.

The main control section 4 is a control center of the image forming apparatus having the main CPU 4a, and has the functional sections 1 to 3 described above.
It also controls the operation of.

These functional units 1 to 3 and main control unit 4
Are respectively connected to the main power source section 6 via the main power source line 8, and are operated by being supplied with main power source from the main power source section 6. Main power supply section 6
Is ON and the main power source 6 supplies main power to the functional units 1 to 3 and the main control unit 4 in a state in which it can be used normally in the image forming apparatus, that is, the function immediately starts. This is a "use mode" in which the operation using parts 1 to 3 is possible.

On the other hand, the standby sub power supply unit 7 is a power supply unit used in the "standby mode" in which energy saving can be achieved.
In the standby mode, the main power supply unit 6 is turned off, and sub power supply is supplied from the standby sub power supply unit 7 to the functional units 1 to 3 through the sub power supply line 9. The standby sub power supply unit 7 is a power supply unit that is never turned off.
The sub power supply line 9 always has a predetermined voltage (sub power supply voltage)
Is being applied. The voltage applied to the sub power supply line 9 is a voltage required in the standby mode and has a lower value than the voltage applied to the main power supply line 8 (main power supply voltage).

The power restoration unit 5 is provided with a sub CPU 5a and outputs a main power ON / OFF signal for controlling ON / OFF of the main power source 6 to the main power source unit 6. The power recovery unit 5 is in a state where the image forming apparatus has the main power supply unit 6 turned on (that is, a use mode)
Then, if the main power supply unit 6 is left unused for a predetermined time, a signal instructing the main power supply unit 6 to be turned off is output to turn off the main power supply unit 6. As a result, the image forming apparatus shifts from the use mode to the standby mode. The power supply restoration unit 5 is adapted to be supplied with sub power from the standby sub power supply unit 7 which is always ON, regardless of ON / OFF operation of the main power supply unit 6.
Always working.

A return signal is input from the functional units 1 to 3 to the power supply return unit 5. When the restoration signal is input, the power restoration section 5 outputs a signal instructing the main power source section 6 to turn on and restores the main power section 6. As a result, the image forming apparatus shifts from the standby mode to the use mode, and main power required for normal operation is supplied to the functional units 1 to 3 and the main control unit 4. The return signal is output when the user operates the functional units 1 to 3.

Then, whether the current state of the image forming apparatus is the use mode or the standby mode is indicated by the light emission indicator mounted on the operation panel section 3.

In the block diagram of FIG. 1, the operation panel section 3 is shown.
The schematic configuration of is shown. As shown in the figure, the operation panel unit 3
Is mainly provided with a mode display unit 12, other display units 16, an input unit 17, a clock generation unit 14, a counter 15, an illuminance sensor 13, and a panel control unit 11. The light emission indicator described above is indicated by 10, and the mode display unit 1
2, clock generator 14, counter 15, illuminance sensor 1
3 and the panel control unit 11.

As described above, the mode display section 12 indicates whether the current state of the image forming apparatus is the use mode or the standby mode, and is composed of a light emitting element. Here, for example, an LED that emits green light is used as the light emitting element, but the invention is not limited to this. The lighting operation of the mode display unit 12 is controlled by the panel control unit 11.

The panel control section 11 controls the operation of each section constituting the operation panel section 3, and is composed of a CPU here. The panel control unit 11 also has a function as a light emission control unit in the light emission indicator 10.
This will be described later. It should be noted that in realizing the control function as the light emission control means in the light emission indicator 10, it may be configured by a logic circuit as described later without using the CPU (see FIG. 12).

The other display section 16 is for displaying information other than the mode display section 12 described above, for example, for displaying information on the selected paper size and the like. Like the mode display unit 12, the other display unit 16 can also be configured by using a light emitting element such as an LED.

The input section 17 is for inputting information to the image forming apparatus, such as a start key for instructing the start of reading a document and a key for inputting a telephone number. In addition,
The other display unit 16 and the input unit 17 can be integrated into one unit using, for example, a touch-type display panel.

The illuminance sensor 13 is a brightness detection sensor for detecting the brightness of the environment in which the image forming apparatus is installed, specifically, the brightness around the mode display section 12 in the light emission indicator 10. The value detected by the illuminance sensor 13 is input to the panel control unit 11, and the mode display unit 12
It is used to control the lighting.

The clock generation unit 14 generates a clock signal, and the generated clock signal is output to the panel control unit 11 and the counter 15 which are CPUs.

The counter 15 blinks the mode display section 12
The light is emitted and the amount of light emitted is pulse-driven,
It is provided to adjust by controlling the width of the
is there. The counter 15 receives the input from the clock generator 14.
D based on the clock signal ₀~ D₁₁Bit of data
This is a 12-bit counter to be created. D₀~ D₁₁bit
Data with a short data value change cycle₀~ D₂Bit
Lower 3 bits of data and long data value change cycle
D₉~ D₁₁The data of the upper 3 bits of the bit is the panel
It is output to the control unit 11.

The lighting control of the mode display section 12 in the panel control section 11 will be described in detail below.

The panel control section 11 lights up the light emitting elements constituting the mode display section 12 to indicate whether the mode is the use mode or the standby mode.

FIGS. 3 and 4A to 4C show an example of lighting when the mode display section functions as a light emission control means for controlling the lighting of the mode display section 12. FIG. 3 shows a light emission waveform in the use mode, and FIGS. 4A to 4C respectively show light emission waveforms in the standby mode. In addition, although it is represented by a rectangular waveform in the figure, in reality, the rising and falling edges of the light emission waveform are broad.

The panel control section 11 is, as shown in FIG.
In the use mode, the mode display section 12 is constantly turned on at the light emission amount level a. On the other hand, in the standby mode, as shown in FIG.
As shown in (a) to (c), the light emission amount levels b to d are lower than the light emission amount level a in the use mode, and the mode is changed while visually recognizing the light emission amount to improve the visibility. The display unit 12 is caused to emit light. As the fluctuation of the light emission amount,
It is blinking here.

The panel control unit 11 selects which one of FIGS. 4A to 4C is to emit light in accordance with the detection result of the illuminance sensor 13. In the case of the present image forming apparatus, the display panel unit 3 is provided with the illuminance sensor 13, and is configured to be able to detect the brightness of the environment in which the image forming apparatus is used. Therefore, the panel control unit 11 causes any one of FIGS. 4A to 4C to emit light based on the information on the ambient brightness detected by the illuminance sensor 13.

The lighting mode in the standby mode shown in FIG. 4A is selected when the surroundings are judged to have normal brightness based on the detection value of the illuminance sensor 13. The normal brightness may be considered as brightness in a general work environment including the image forming apparatus. The determination of brightness based on the detection value from the illuminance sensor 13 in the panel control unit 11 is performed based on a predetermined standard. If the detected value belongs to a certain reference range, it is determined to be normal brightness, and if it exceeds the range, it is determined to be bright or dark surroundings depending on whether it is brighter or darker. . The user may freely set the range that serves as the criterion for determining the brightness.

In the lighting mode of the standby mode, the mode display portion 12 is blinked and turned on at a light emission amount level b at which it can be visually recognized that the mode display portion 12 is blinked and turned on when the surroundings have normal brightness. By blinking and lighting, power consumption can be suppressed as compared with constant lighting. Moreover, because the blinking lighting improves the visibility compared to the constant lighting,
The light emission amount level b that is set to be visible when the surroundings are in normal brightness can be set to a value lower than the value in the case where the light is constantly turned on, and this also further effectively reduces power consumption. It can be reduced. Here, the ON period T _on 1 and the OFF period T _off are flickered at a cycle of 3, but this is merely an example, and may be appropriately set in consideration of visibility.

The lighting mode in the standby mode shown in FIG. 4B is selected when it is determined that the surroundings are brighter than the detected value of the illuminance sensor 13. In the lighting mode,
Even when the surroundings are bright, the mode display section 12 is blinked and lit at a light emission amount level c (level a> level c> level b) at which it can be visually recognized that the mode indicator 12 is lit. Also in this case,
By blinking and lighting, power consumption can be suppressed as compared with constant lighting. Moreover, by blinking and lighting,
Since the visibility is improved as compared with the constant lighting, the light emission amount level c set so that it can be visually recognized even if the surroundings are bright,
The value can be set lower than the value in the case of constant lighting, and also by this, the power consumption can be further effectively reduced.

In this case, since the surroundings are bright, the light emission level of the mode display section 12 is set to the level a in the use mode.
Since it is set to a high level, although it is not so high, when the LED is turned _on and _off , the ON period T _on is turned _on as short as possible with respect to the OFF period T _off . As a result, it is possible to totally reduce the power consumption required to light the mode display unit 12 even though the required light emission amount is high. Here, as an example, the ON period T _on 1 and the OFF period T _off are made to blink and light at a cycle of 7.

The lighting mode in the standby mode shown in FIG. 4C is selected when it is determined that the surroundings are darker than the detected value of the illuminance sensor 13. When the surroundings are dark, it is possible to visually recognize that the mode display unit 12 is lit even with a small amount of light emission. Therefore, in the lighting mode, when the surroundings are dark,
In addition, the light emission amount level d (level a> level c) at which power consumption is suppressed as much as possible so that the blinking lighting can be visually recognized.
> Level b> Level d) The light is turned on and off. Also in this case, the blinking lighting can reduce power consumption as compared with the constant lighting. Moreover, the blinking lighting improves the visibility as compared with the continuous lighting, and thus the light emission amount level d is set so that it can be visually recognized in a dark surrounding.
Can be set to a value lower than the value for constant lighting, which also enables effective reduction in power consumption.

In this case, on the contrary to the standby mode, the amount of light emission of the mode display section 12 is suppressed as much as possible due to the dark surroundings.
Even if the ON period T _on with respect to the period T _off is made longer than in other standby modes, power consumption can be suppressed. Here, as an example, OF is applied to the ON period T _on 1.
The F period T _{off is set} to 1 in a blinking manner.

As described above, the image forming apparatus is provided with the illuminance sensor 13, and the panel control unit 11 is configured to select one of the lighting modes from the standby mode to the lighting mode according to the ambient brightness. Therefore, the mode display unit 12
The degree of decrease in the amount of emitted light and the degree of change in the amount of emitted light can be set according to the brightness of the surroundings of the mode display unit 12, and it is possible to effectively save power without impairing the visibility.

The illuminance sensor 13 does not necessarily have to be provided, and the lighting mode in the standby mode may be fixed to the lighting mode in the standby mode when the surroundings have normal brightness. In that case, although the illuminance sensor 13 is provided and the lighting of the mode display unit 12 is not controlled according to the ambient brightness, the power consumption required for lighting the mode display unit 12 in the standby mode is different from that in the use mode. This can be sufficiently suppressed as compared with the configuration of lighting in the same lighting state.

Although not described above, the mode display section 12 is also turned on to indicate that the power indicating that the image forming apparatus is turned on is turned on or off. By lighting the mode display unit 12 as described above, one mode display unit 12 can be used to indicate the use mode (= power ON) and the standby mode in addition to the ON / OFF state of the power of the image forming apparatus. You can

The light emitting element forming the mode display section 12 is L
In the case of ED, since the light emission amount is proportional to the current, the light emission amount levels b to d in FIGS. 4A to 4C described above are as shown in FIG.
This can be easily realized by setting the current value lower than the current value that causes the mode display unit 12 to emit light at the light emission amount level a in the use mode shown in.

Further, the light emission amount levels b to d in FIGS. 4 (a) to 4 (c) do not directly control the amount of current, but the current and voltage are kept at a constant level and pulsed in an invisible period. It is also possible to drive and control the pulse width at that time to adjust the light emission amount to reduce the light emission amount. When the predetermined light emission amount level is set by the pulse width control, the light emission is performed by blinking in a cycle that cannot be visually recognized. Therefore, the power consumption can be further reduced by the method of changing the current amount. In this image forming apparatus, the amount of light emission is controlled by this pulse width control.

In FIGS. 5A to 5C, the standby mode is shown.
The waveforms of the drive signals output from the panel control unit 11 to the mode display unit 12 in the respective lighting modes are shown. As shown in the figure, in the adjustment of the light emission amount by the pulse width control, the light emission amount increases in proportion to the ratio of the ON period t _on in one cycle at the time of pulse driving. Mode, O for the OFF period t _off
Pulse width is set to N period t _on the longest,
In the standby mode, which is selected when the surroundings are dark, the OF
The ON period t _on with respect to the F period t _off is set to be the smallest.

[0060] As one example, where, in the standby mode, and 3 the OFF period t _off to the ON period t _on 1, in the standby mode, and 1 OFF period t _off to the ON period t _on 1 , In standby mode,
Pulse driving is performed with the OFF period t _{off set} to 7 for the ON period t _on 1.

Further, in the image forming apparatus, by using the D _{0 to} D ₁₁ bit data generated by the clock 15, the blinking lighting control shown in FIGS. 4A to 4C is performed. , And the control of the light emission amount by the pulse width control shown in FIGS. 5A to 5C are integrated.

That is, pulse width control is performed by using the lower 3 bits of data D _{0 to} D ₂ bits having a short data value change cycle generated by the clock 15, and D _{9 to} D _{11 having} a long data value change cycle. Blinking control is performed using the upper 3 bits of data. FIG. 6 shows a control table used by the panel control unit 11 in lighting the mode display unit 12 in the lighting modes from the standby mode to the above.

As shown in the figure, the surroundings have normal brightness.
If the standby mode selected, the data value change cycle
Long D₉~ D₁₁Bit data indicates "0 to 1"
It is turned on only in the case of "2-7" and turned off.
It As a result, the ON period T shown in FIG._onTo 1
For OFF period T_offIs lit in a cycle of 3
It And the ON period T_onIn addition, the data
D with short value change cycle₀~ D₂Bit data is "2-
When it indicates "3", it is turned on, and "0 to 1" and "4 to 7"
Is turned off. As a result, as shown in FIG.
Shows the ON period t _onOFF period t for 1_off Set to 3
It is pulse-driven at a fixed cycle.

In the standby mode, which is selected when the surroundings are bright, the D _{9 to} D ₁₁ bit data, which has a long data value change cycle, is turned on only when the data indicates "0", and "1 to
If it indicates "7", it is turned off. As a result, FIG.
The OFF period T _off is shown for the ON period T _on 1 shown in (b).
Is turned on and off in a cycle of 7. And the ON period T
_{In on} , D ₀ to
When the D ₂ bit data indicates “2 to 5”, it is turned on, and when it indicates “0 to 1” and “6 to 7,” it is turned off. As a result, the ON period t _on 1 shown in FIG.
On the other hand, pulse driving is performed in a cycle in which the OFF period t _off is 1.

[0065] In the standby mode the ambient is selected when dark, long D ₉ to D ₁₁ bits of data of the data value change period, are ON to indicate "0-3", "4
If it indicates "7", it is turned off. As a result, FIG.
The OFF period T _off is shown for the ON period T _on 1 shown in (c).
The light is turned on and off in a cycle of 1. And the ON period T
_{In on} , D ₀ to
Turned ON only when the D ₂ bit data indicates 2,
When it indicates "0 to 1" and "3 to 7," it is turned off. As a result, pulse driving is performed in the cycle shown in FIG. 5C in which the OFF period t _off is 7 with respect to the ON period t _on 1.

In the flow chart of FIG. 7, the panel control unit 1
The procedure of lighting control of the mode display part 12 in 1 is shown.

The panel control section 11 detects whether or not the rising edge of the clock signal (S1). When the rising edge is detected, the panel control section 11 judges whether or not the main power source section 6 is turned on (S2). If it is determined that the main power supply unit 6 is turned on, the process proceeds to S7, and the mode display unit 12
Is turned on, and then the process returns to S1. That is, the main power supply unit 6
When is turned on and the main power is supplied to the panel control unit 11, the processes of S1 and S7 are repeated, and the mode display unit 1 is detected each time the rising edge of the clock signal is detected.
Turn on 2. As a result, the mode display unit 12 is in a state of being constantly lit with a light emission amount in the use mode higher than the ON period T _{on in} the standby mode.

On the other hand, in S2, the main power supply unit 6 is turned off.
If it is determined that the illuminance sensor 13
The ON / OFF count value of the mode display unit 12 is set based on the output from the. That is, based on the control table of FIG. 6, the lighting state according to the brightness of the surroundings detected by the illuminance sensor 13 is selected from the standby mode to, and ON / OFF at the time of pulse width control and blinking control is selected. Set the OFF count.

Next, from the data of D _{0 to} D ₂ bits, it is judged whether or not this timing is the ON period t _on of the pulse driving (S4), and if it is judged that it is the ON period t _on ,
Subsequently, it is determined from the D _{9 to} D ₁₁ bit data whether this timing is the ON period T _on of the blink control.
5). Then, when it is determined that the ON period T _on is again here, the mode display unit 12 is turned _on (S7), and then S1
Return to. That is, only when both S4 and S5 are determined to be yes, the process proceeds to S7 and the mode display unit 12 is turned on. Further, in S4, it is determined that the ON period t _on of the pulse drive is not on, or in S5, the blinking control O
If it is determined not to N period T _on, the mode display unit 12
Is turned off (S6), and the process returns to S1.

As a result, the mode display section 12 is turned _on only during the ON period T _on of blinking lighting and the ON period t _on of the pulse drive while the rising of the clock signal is detected, and other than that. At the timing of
The mode display unit 12 is turned off. Compared with the use mode in which the user is always turned on at the rising edge of the clock signal, the user can see the O at a cycle invisible by pulse driving.
Amount that is N time t _on decimated, appears as a weak light emission amount, even though light emission amount is low, since visibility is improved by being blinking, it is an image forming apparatus without any problem in the standby mode Can be recognized.

Further, in the above description, when the mode display section 12 is turned on and off, it is exemplified that the mode display section 12 is turned on and off at regular intervals. However, the ON period and the OFF period during which the blinking is turned on are set at random. It may be configured to blink irregularly. Further, as a method of improving the visibility, here, a configuration in which the light is turned on and off is used, but the mode display unit 12 is always turned on, that is, the OFF period (different from the OFF period of pulse driving) is not provided, May be changed to a constant cycle or a random cycle. Further, only the amount of light emission during the ON period of blinking lighting may be randomly changed, or the length of the ON period of blinking lighting in which the amount of light emission changes at random periods may be changed randomly.

Further, a blinking and lighting cycle, and / or
The pulse width during the pulse width control for controlling the light emission amount may be set by the user himself / herself.

A case will be described below with reference to FIGS. 8 to 10 in which the pulse width during pulse driving is set randomly and the blinking lighting period is set by the user. In addition, the illuminance sensor 13 is not installed here.

FIG. 8 shows the case where the panel control unit 1 is used when the ratio setting of the ON / OFF period of pulse driving is set randomly.
1 shows a control table used by No. 1. In the figure, "X" is a randomly set value, and X takes a numerical value of "3 to 6". When D _{0 to} D ₂ bit data having a short data value change cycle indicates _{2 to} X, it is turned ON, and 0 to 1 and (X +
When 1) to 7 are indicated, it is turned off.

Further, FIG. 9 shows a control table used by the panel control section 11 when the ratio setting of the ON / OFF period of blinking lighting is set as the user setting. In the figure, "Y"
Is a value set by the user, and Y takes a numerical value of “0 to 6”. A data value change period longer D ₉ to D ₁₁ bits of data, are ON when indicating the 0~Y, (Y + 1) ~7
Is turned off.

The flowchart of FIG. 10 shows the procedure for controlling the lighting of the mode display section 12 in the panel control section 11 in this case.

The panel control section 11 first sets an ON / OFF count for blink control based on the control table of FIG. 9 (S11). Next, it is determined whether or not the clock signal is the rising edge (S12), and when the rising edge is detected, it is subsequently determined whether or not the main power supply unit 6 is turned on (S13). Here, the main power supply unit 6
When it is determined that is turned on, the process proceeds to S19, the mode display unit 12 is turned on, and then the process returns to S12. That is, when the main power supply unit 6 is turned on and the main power supply is supplied to the panel control unit 11, S12, S1
The process of 9 is repeated, and the mode display unit 12 is turned on each time the rising edge of the clock signal is detected. As a result, the mode display unit 12 is in a state of being constantly lit with a light emission amount in the use mode higher than the ON period T _{on in} the standby mode.

On the other hand, in S13, the main power supply unit 6 is turned off.
If it is determined that the F driving is performed, the process proceeds to S14, and from the data of D _{0 to} D ₂ bits, this timing is ON of the pulse driving.
If it is determined that it is a period, and if it is determined that it is an ON period, it is subsequently determined from the data of bits D _{9 to} D ₁₁ whether this timing is the ON period of blinking control (S
15). Then, if it is determined that it is the ON period also here, the mode display unit 12 is turned ON (S19), and then S
Return to 12. That is, only when both S14 and S15 are determined to be yes, the process proceeds to S19 and the mode display unit 12
Turn on. Further, in S14, the pulse drive is turned on.
If it is determined that it is not during the period, or if it is determined in S15 that it is not during the blinking control ON period, the mode display unit 12 is turned off (S16), and the process proceeds to S17.
, The output from the counter 15 is D _{0 to} D ₁₁
It is determined whether all the bit data are "0". If all the bits are "0", the random value X in the pulse drive is set (S18), and the process returns to S12. In addition,
If all are not "0", the process directly returns to S12. An initial value is set as the random value X, and the initial value is used until the random value X is first set in S18.

As a result, while the rising edge of the clock signal is detected, the mode display section 12 is turned on only during the flashing lighting ON period set by the user and at the timing of the pulse driving ON period randomly set. At other timings, the mode display unit 12 is turned off. In addition to the blinking lighting, the visibility is further improved by randomly changing the light emission amount during lighting, so that the user can recognize that the image forming apparatus is in the standby mode without any problem.

Further, in the above description, the mode display section 12 is constructed by using one light emitting element to control the lighting state of one light emitting element, but as shown by the broken line in FIG. In addition to the light emitting element that emits green light, a light emitting element 12a that emits red light is provided, and the mode display unit 12 is configured by a plurality of light emitting elements, and as a method of improving the visibility in the standby mode to compensate for the reduction of the light emission amount, A configuration in which a plurality of light emitting elements are alternately turned on may be adopted.

FIG. 11 shows a blinking control table used by the panel control unit 11 when the mode display unit 12 has two light emitting elements. In the figure, ON1 indicates, for example, an ON period of a green light emitting element, and ON
Reference numeral 2 indicates the ON period of the red light emitting element. For the green light emitting element, the data of D _{9 to} D ₁₁ bits is "0
It is turned on when "1" is shown, and O when "2-7" is shown.
FF is done. On the other hand, the red light emitting element is turned on when it shows "2 to 3" and turned off when it shows "0 to 1" and "4 to 7".

Further, in the above description, the function as the light emission control means in the light emission indicator 10 is realized by using the CPU, but it may be constituted by a logic circuit as shown in FIG. it can. With the configuration shown in FIG. 12, it is possible to perform control according to the control table shown in FIG.

Here, the light emission control unit 30 includes the first and second decoders 21 and 22 and the first and second comparators 2.
3, 24, a pulse driving logic circuit 25, a blinking logic circuit 26, an AND circuit 27, and an OR circuit 28.

The first comparator 23 includes an illuminance sensor 13
Is compared with the reference voltage, "1" is output when the surroundings are bright, and "0" is output otherwise. on the other hand,
The second comparator compares the output of the illuminance sensor 13 with its reference voltage, and outputs "1" when the surroundings are bright and when the brightness is normal (in the figure, described as "intermediate brightness" is "medium"). Output, and output "0" when it is dark.

The first and second decoders 21 and 22 are 3
Depending on the contents of the bit data, there are 8 outputs 0 to 7
It outputs "1" to it. Of these, the first
The output of the pulse driving counter 15 is supplied to the coder 21.
Some D₀~ D₂Bit decoder is input and the second decoder
22 is the output of the counter 15 for blink control ₉
~ D₁₁Bit data is input.

Of the eight outputs of the first decoder 21, the output 6
7 is not connected to the pulse driving logic circuit 25. Therefore, at the timing when the outputs 6 and 7 are selected, the signal output from the pulse driving logic circuit 25 is always "0". Further, the output 0 · 1 of the first decoder 21 is connected to the AND circuit 25-0 · 25-1 out of the six AND circuits 25-0 to 25-5 forming the pulse driving logic circuit 25 together with the GND. It has been entered. Therefore, the outputs of the AND circuits 25-0 and 25-1 are always "0" regardless of the values of the outputs 0 and 1 of the first decoder 21.

On the other hand, the output 2 of the first decoder 21
Is input to the AND circuit 25-2 together with Vcc. Therefore, the output of the AND circuit 25-2 is the first
It is always "1" regardless of the value of the output 2 of the decoder 21.

The output 3 of the first decoder 21 is input to the AND circuit 25-3 together with the output of the second comparator 24. Therefore, the output of the AND circuit 25-3 is such that the output 3 of the first decoder 21 is "1" and the second
"1" only when the output of the comparator 24 is "1"
Becomes As described above, the output of the second comparator 24 becomes "1" when the ambient brightness is bright and when the brightness is normal.

The outputs 4 and 5 of the first decoder 21 are input to the AND circuits 25-4 and 25-5 together with the output of the first comparator 23. Therefore, the AND circuit 25-
The output of 4.25-5 is the output of the first decoder 21.
Is "1" and the output of the first comparator 23 is "1" only. The output of the first comparator 23 becomes "1" when the ambient brightness is bright.

The outputs of the AND circuits 25-0 to 25-5 are input to the OR circuit 25a. OR circuit 2
The output of 5a becomes "1" except when all the inputs are "0", and is input to the AND circuit 27.

On the other hand, of the eight outputs of the second decoder 22,
Since the outputs 4 to 7 are not connected to the blinking logic circuit 26, at the timing when the outputs 4 to 7 are selected,
The signal output from the blinking logic circuit 26 is always "0". In addition, the output 0 of the second decoder 22 is the four AND circuits 26 constituting the blinking logic circuit 26.
Vcc is applied to the AND circuit 26-0 of -0 to 26-3.
Is entered with. Therefore, the AND circuit 26
The output of −0 is always “1” regardless of the value of the output 0 of the second decoder 22.

The output 1 of the second decoder 22 is input to the AND circuit 26-1 together with the output of the first comparator 23. Therefore, the output of the AND circuit 26-1 becomes "1" only when the output 3 of the first decoder 21 is "1" and the output of the first comparator 23 is "0". The output of the first comparator 23 is "0"
Is when the surrounding brightness is dark and when the brightness is normal.

The outputs 2.3 of the second decoder 22 are input to the AND circuits 26-2 and 26-3 together with the inverted output of the second comparator 24. Therefore, the AND circuit 2
The outputs of 6-2 and 26-3 are the outputs 2 of the second decoder 22.
Only when 3 is "1" and the output of the second comparator 24 is "0", is "1". The output of the second comparator 24 becomes “0” when the ambient brightness is dark.

The AND circuits 26-0 to 26- are provided.
The outputs of 3 are input to the OR circuit 26a. The output of the OR circuit 26a becomes "1" and is input to the AND circuit 27 except when all the inputs are "0".

The output of the pulse driving logic circuit 25 and the output of the blinking logic circuit 26 are input to the AND circuit 27, and the output thereof is the pulse driving logic circuit 2.
It becomes "1" only when both the output of 5 and the output of the blinking logic circuit 26 are "1".

The output of the AND circuit 27 is input together with the main power supply to the OR circuit 28 whose output side is connected to the mode display section 12. The output of the OR circuit 28 is such that the main power supply is "0", that is, OFF, and the AND circuit 2
It becomes "0" only when the output of 7 is "0", and becomes "1" when either one is "1".

When the function as the light emission control means in the light emission indicator 10 is realized by using a CPU, fine and flexible control of the light emission amount can be easily performed. Although it is not possible to easily control the amount of light emission so finely and flexibly,
Since the clock-driven CPU is not used, there is an advantage that the power consumption in the standby mode can be suppressed more than when the CPU is used.

[0098]

As described above, the light emission indicator of the present invention has the following features.
It is installed in various devices, and by turning on the light emitting element,
A light emission indicator that indicates at least whether the device is in a normal use mode or in a standby mode with reduced power consumption, wherein the light emission amount of the light emitting element in the standby mode is the light emission in the use mode. Lower than the amount,
It is characterized in that a light emission control means for changing the light emission amount in a visible cycle is provided.

According to this, since the light emission control means reduces the light emission amount of the light emitting element in the standby mode to be lower than the light emission amount in the use mode, the amount of power consumed in the light emission indicator in the standby mode is changed to the use mode. It can be kept lower than the amount of electric power at that time. Moreover, the light emission control means does not simply decrease the light emission amount but changes the light emission amount in a visually recognizable cycle. It becomes possible to compensate for the deterioration of sex. Further, the visibility due to the variation of the light emission amount is improved, and the light emission amount in the standby mode can be reduced more effectively.

Therefore, in a device having a standby mode, low power consumption is ensured while ensuring good visibility as to whether the current state of the device is a normally usable use mode or a standby mode. There is an effect that it is possible to provide a light emission indicator which can be indicated by.

The fluctuation of the light emission amount by the light emission control means is
It may be changed in a constant cycle or in a random cycle in which the fluctuation cycle is irregular. By changing the amount of light emission at random, the change in the amount of emitted light becomes irregular, and the visibility is further improved.

Further, as the variation of the light emission amount by the light emission control means, the light emitting element may be turned on and off. Also in this case, by making the blinking cycle random, the blinking becomes irregular and the visibility is further improved.

Further, a plurality of light emitting elements may be provided, and the light emission control means may alternatively and alternately light up the plurality of light emitting elements to change the light emission amount.
In this case, since any one of the plurality of light emitting elements is lit, even if the lighting cycle of one element is lengthened, there is an effect that the risk of misidentifying it as being turned off is reduced.

Further, in the structure in which a plurality of light emitting elements are alternately turned on, it is more preferable that each light emitting color of the plurality of light emitting elements includes a combination of at least two colors. Since the color changes in addition to the change in the amount of light emitted,
This has the effect of further improving the visibility.

Further, the light emission control means may control the light emission amount of the light emitting element by pulse-driving the light emitting element in a non-visible period and controlling the pulse width thereof.

The method of pulse-driving the light emitting element and controlling the pulse width at that time to control the amount of light emission is necessary for obtaining the same amount of light emission as compared with the method of controlling the amount of light emission by controlling the amount of current. Since it is possible to reduce the amount of power consumption, it is more preferable in terms of power saving. Further, by controlling the amount of light emission by pulse driving, control for reducing the amount of light emission and control for changing the amount of light emission can be performed in an integrated manner, so that the processing is facilitated. The effect is played together.

Further, the above-mentioned light emission indicator of the present invention further comprises brightness detection means for detecting the brightness around the light emission indicator such as a place where the device equipped with the light emission indicator is used. However, the light emission control means may be characterized by controlling the degree of decrease in the light emission amount according to the detection value of the brightness detection means.

According to this, since the light emission control means controls the degree of decrease in the light emission amount according to the detection value of the brightness detection means for detecting the brightness around the light emission indicator, the light emission amount of the light emitting element is controlled. It can be adjusted according to the brightness of the surroundings. In other words, when the surroundings are dark, it is possible to visually recognize even a small amount of light emission. Therefore, when the surroundings are dark, the decrease amount of the amount of light emission is increased. The lower the amount of light emission, the less likely it is to be mistaken for turning off the light. As a result, there is an effect that the power can be saved more effectively without impairing the visibility.

Further, in this case, the light emission control means may further control the degree of change in the visible light emission amount according to the detection value of the brightness detection means.

The brighter the surroundings, the smaller the amount of decrease in the amount of light emitted from the light emitting element and the higher the power consumption. Therefore, the amount of light emission cannot be reduced, so that the variation in the amount of light emission is controlled to reduce the overall power consumption. Try to keep it down.

That is, when the light emitting element is turned on and off,
The variation may be adjusted so as to shorten the lighting time.
As a result, there is an effect that power can be saved more effectively without impairing the visibility.

The light emission control means can be composed of a CPU. In this case, the effect that the fine and flexible control of the light emission amount can be easily performed is also provided.

The light emission control means may be composed of a logic circuit. If it is composed of logic circuits,
Since the clock-driven CPU is not used, the power consumption in the standby mode can be suppressed more than when the CPU is used.

[Brief description of drawings]

FIG. 1 is a block diagram showing a configuration of an operation panel unit of an image forming apparatus in which a light emission indicator is mounted according to an embodiment of the present invention.

FIG. 2 is a block diagram showing a configuration of the image forming apparatus.

FIG. 3 is a diagram showing a light emission amount in a use mode in the light emitting element of the light emission indicator.

FIGS. 4A to 4C are diagrams showing the amount of light emission in the standby mode in the light emitting element of the light emission indicator.

5A to 5C are diagrams showing drive signals in a standby mode in the light emitting element of the light emission indicator.

FIG. 6 is a drawing showing a control table for pulse drive control and blink control used for lighting control of a light emitting element in the light emission indicator.

FIG. 7 is a flowchart showing a procedure of lighting control of a light emitting element in the light emission indicator.

FIG. 8 is a view showing another embodiment of the present invention and showing a control table of pulse drive control used for lighting control of a light emitting element in a light emission indicator.

FIG. 9 is a drawing showing a control table of blinking control used for lighting control of a light emitting element in the light emission indicator.

FIG. 10 is a flowchart showing a procedure of lighting control of a light emitting element in the light emission indicator.

FIG. 11 is a view showing yet another embodiment of the present invention and is a drawing showing a control table of blinking control used for lighting control of a light emitting element in a light emission indicator.

FIG. 12 is a circuit diagram showing a configuration of a control means for controlling lighting of a light emitting element in a light emission indicator, showing still another embodiment of the present invention.

[Explanation of symbols]

1 Facsimile department 2 Printer section 3 Operation panel section 6 Main power supply 7 Standby power supply 10 Light emission indicator 11 Panel control unit (light emission control means) 12 Mode display (light emitting element) 13 Illuminance sensor (brightness detection means) 30 Light emission control unit

─────────────────────────────────────────────────── ─── Continuation of front page (51) Int.Cl. ⁷ Identification code FI theme code (reference) G09G 3/14 G06F 1/00 332Z F term (reference) 2C061 AP03 AP04 CQ22 CQ28 CQ30 HH11 HJ07 HT01 5B011 DC06 DC07 EA10 EB08 LL05 LL06 5C080 AA07 BB09 DD26 EE15 EE16 JJ02 JJ03 JJ04 5C096 AA01 AA02 AA21 BA04 BC02 BC04 CA06 CA12 CA32 CC07 DC02 DC03 DC05 DC06 DC10 DC11 DC15 DC19 DC29 DC30 FA12 FA17

Claims (12)

[Claims] 1. A light emission instruction which is mounted on various devices and which lights a light emitting element to indicate whether the device is in a normal use mode or in a standby mode in which power consumption is reduced. In a standby mode, the light emission amount of the light emitting element is lower than the light emission amount in the use mode, and a light emission control means for varying the light emission amount in a visible cycle is provided. vessel. 2. The light emission indicator according to claim 1, wherein the light emission control means changes the light emission amount in a constant cycle. 3. The light emission indicator according to claim 1, wherein the light emission control means changes the light emission amount in a random cycle. 4. The light emission indicator according to claim 2, wherein the light emission control means changes the light emission amount by blinking and lighting the light emitting element. 5. A plurality of the light emitting elements are provided, and the light emission control means varies the light emission amount by selectively alternately lighting the plurality of light emitting elements. The light emission indicator described in. 6. The light emitting indicator according to claim 5, wherein each of the light emitting colors of the plurality of light emitting elements includes a combination of at least two colors. 7. The light emission control means controls the pulse width by pulse-driving the light-emitting element at a period invisible.
The light emission indicator according to any one of claims 1 to 6, wherein the light emission amount is controlled. 8. A brightness detecting means for detecting brightness around a light emitting indicator such as a place where a device equipped with the light emitting indicator is used, and the light emission controlling means comprises the brightness detecting means. The light emission indicator according to any one of claims 1 to 7, wherein the degree of decrease in the amount of light emission is controlled according to the detection value of. 9. The light emission indicator according to claim 8, wherein the light emission control means controls the degree of visible change of the light emission amount according to the detection value of the brightness detection means. 10. The light emission indicator according to claim 9, wherein the light emission control means controls such that the lighter the surroundings of the light emission indicator, the shorter the lighting time of the light emitting element when blinking. . 11. The light emission indicator according to claim 1, wherein the light emission control means comprises a CPU. 12. The light emission indicator according to claim 1, wherein the light emission control means is composed of a logic circuit.