JP2000324692A - Power controller, power control method, and storage media having stored program and data - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress the rush current and higher harmonic current at power on, by limiting the phase angle of the AC current to be supplied on the basis of the temperature detected with a temperature detection means to a designated phase angle, when turning on power to a heating means or cutting it off. SOLUTION: An AC power source is used for a heater source 501, a heater 502 being a heating means is supplied with power through a switch 507, the temperature of the heater 502 is detected with a temperature sensor 503 and a temperature detecting circuit 504, and resistance is computed from the temperature of the heater 502 with a computing circuit 505. In case that there is a difference of temperature in a heater 502 at power supply by this computation, such soft start as to start the phase angle at a designated phase angle near to roughly 0 deg. as an input current waveform and to increase the phase angle gradually for each additional Hz to full lighting is performed. As a result, the rush current at power on and the higher harmonic current can be suppressed.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a power supply control device, a power supply control method, and a storage medium storing a program and data, and more particularly to suppression of an inrush power supply, suppression of a harmonic current, and suppression of a power supply voltage fluctuation when power is turned on / off. The present invention relates to a power supply control device, a power supply control method, and a storage medium storing a program and data.

[0002]

2. Description of the Related Art Harmonic current regulations (IEC1000-3-2) and power supply voltage fluctuation regulations (IEC1000-3-3) are part of the European CE mark. Harmonic current regulation (IEC1000-3-2) is an international standard on "limit value for outflow of harmonic current (devices whose input current per phase is 16 amps or less)", and IEC on conventional harmonic current. It is a revision of the standard 555-2.
The power supply voltage fluctuation regulation (IEC1000-3-3) is an international standard related to “voltage fluctuation and flicker limit value of equipment having an input current per phase of 16 amps or less”.
This is a revision of the conventional IEC standard 555-3 on voltage fluctuation.

[0003] Most of the old electric products include resistive loads such as incandescent lamps and electric heaters, and inductive loads such as motors. Here, the inductive load delays the phase of the current, but no harmonic is generated because the current waveform remains a sine wave.

However, in recent years, the number of electrical products that use DC in devices such as TV sets, personal computers, and inverter air conditioners has increased, and rectifier circuits for converting AC to DC have become loads. FIG. 1 shows a capacitor input type rectifier circuit having the simplest configuration among conventional rectifier circuits. FIG. 2 shows current and voltage waveforms of respective parts obtained from the capacitor input type rectifier circuit of FIG.

In FIG. 1, since the period during which the AC input current IAC102 flows is limited to the period for charging the capacitor C120, the instantaneous value of the input voltage VAC101 is
The current flows only when the voltage becomes higher than the voltage VDC 121 of FIG. Therefore, the waveform of the IAC 102 has a pulse shape, which is significantly different from the input voltage waveform. Such a current waveform contains many harmonic currents.

[0006] Flicker is defined as "impression of visual sensation instability caused by light stimulus due to temporal fluctuation of luminance or spectrum distribution". In other words, it can be said that it is possible to quantitatively evaluate the degree of fluctuation (flicker) of brightness felt by humans. The light in the room may be dark at the moment when a motor device such as a refrigerator or a vacuum cleaner operates. This is a flicker that occurs when a large current flows when the motor is started and the voltage is reduced by the distribution impedance.

However, refrigerators, electric water heaters, air conditioners (not inverter type), etc. are always ON / OF.
Since F is repeated, a sudden voltage change cannot be avoided. In addition, when an incandescent light bulb is used for lighting, the brightness of the light bulb, that is, flicker, is affected by the square of the voltage change because the brightness of the light bulb is proportional to the input power.

As a first technical example for solving such a problem, Japanese Patent Application Laid-Open No. Hei 3-113519 discloses a heater control device using phase control during a transition period after power is turned on.

As a second conventional example, in particular, in a power supply device of an OA device such as an electrophotographic machine (hereinafter simply referred to as a copier) or a laser printer, a small and light weight, low cost, high conversion efficiency, and excellent low voltage are provided. A switching power supply (also referred to as a switching power supply) including a DC-DC converter in a circuit configuration, which is a DC power supply device having characteristics.
There is known a method of suppressing power supply voltage fluctuations by using power supply voltage. This switching regulator requires rectifying and smoothing means for rectifying and smoothing the AC input in order to obtain an input to the DC-DC converter, but generally, the AC input is full-wave rectified to perform a capacitor input type. Means for smoothing by a smoothing circuit is employed.

[0010]

However, in the method of the prior art 1 described above, when the heater is controlled by phase control, the commercial power supply contains a harmonic current, and after the transition period has elapsed, the heater is turned on.
Only / OFF control is performed and power supply voltage fluctuation control is not performed.
In other words, the purpose of this technique is to suppress inrush power, and since the heater is controlled only during the transition period when the power is turned on by phase control, ON / OFF control is performed after the transition period, and power supply voltage fluctuations increase. .

Here, in order to suppress the harmonic current, there is a method in which the heater control is turned on / off and the input current waveform is made a sine wave. However, in this method, the rush power to the heater becomes large, There is a problem that power supply voltage fluctuations increase.

In order to suppress fluctuations in the power supply voltage, there is a method of performing phase control on the heater control. However, this method has a problem that a harmonic current is superimposed on an input current of the heater.

As described above, it is necessary to take countermeasures against both the harmonic current regulation and the power supply voltage regulation.
There is a need for a technique to solve this problem.

Further, in the method of the second conventional example, when a capacitor input type smoothing circuit is used, the DC-D
The input current waveform of the C converter is distorted like a pulse, and the harmonic current is significantly increased. This harmonic current is converted into a commercial power supply voltage distortion by a commercial power supply line impedance, which is an AC input, and causes troubles such as abnormal noise and burnout in electric equipment and distribution equipment connected to the commercial power supply.

SUMMARY OF THE INVENTION The present invention has been made in view of the above problems, and has a power supply control device, a power supply control method, and a program and a data storage for enabling both harmonic current regulation and power supply voltage variation regulation to be solved. The purpose is to provide a medium.

[0016]

In order to achieve the above object, the invention according to claim 1 comprises AC power supply means for supplying AC power, such as a commercial power supply, and a resistor or a Peltier element. Heating means, a temperature detection means for detecting the temperature of a load constituting the heating means, and a phase angle of alternating-current power supplied based on the temperature detected by the temperature detection means when power is turned on or off to the heating means. And control means for limiting the phase angle to a designated phase angle.

Therefore, according to the present invention, it is possible to suppress the inrush power supply and the harmonic current when the power is turned on, and to prevent the influence of the harmonic current on other devices that obtain power from the same power supply. .

Further, according to the present invention, an AC power supply means for supplying AC power, such as a commercial power supply,
Heating means including a resistor or a Peltier element, and temperature detection means for detecting the temperature of a load constituting the heating means,
When power is supplied to the heating means, the phase angle of the AC power supplied based on the temperature detected by the temperature detection means is set to approximately 0.
Control means for performing a soft start control in which the phase angle is increased at a first designated phase angle close to ° and the phase angle is gradually increased every predetermined cycle until all the lights are turned on (phase angle 180 °).

Therefore, according to the present invention, it is possible to suppress the inrush power supply and the harmonic current at the time of turning on the power supply, and to prevent the influence of the harmonic current on other devices that obtain power from the same power supply. .

Further, according to the present invention, an AC power supply means for supplying AC power, such as a commercial power supply,
Heating means including a resistor or a Peltier element, and temperature detection means for detecting the temperature of a load constituting the heating means,
When power is supplied to the heating means, the phase angle of the AC power supplied based on the temperature detected by the temperature detection means is set to approximately 0.
When starting at a first designated phase angle close to ° and performing soft start control in which the phase angle is gradually increased at predetermined intervals until full lighting (phase angle of 180 °), power is cut off to the heating means. Control means for performing soft-stop control in which the phase angle is raised at a second designated phase angle close to approximately 180 °, and thereafter the phase angle is gradually reduced at predetermined intervals until all lights are turned off (phase angle 0 °). And

Therefore, according to the present invention, it is possible to suppress the rush power supply and the harmonic current at the time of turning on and off the power supply, and to prevent the influence of the harmonic current on other devices that obtain power from the same power supply. Becomes

According to a fourth aspect of the present invention, there is provided an AC power supply means for supplying AC power, such as a commercial power supply.
Heating means including a resistor or a Peltier element, and temperature detection means for detecting the temperature of a load constituting the heating means,
A control unit for limiting the phase angle of the AC power supplied based on the temperature detected by the temperature detection unit to a specified phase angle when turning on or off the power to the heating unit, and an AC supplied by the AC power supply unit. Rectifying and smoothing the current,
Rectifying / smoothing means including an active filter circuit or the like.

Therefore, according to the present invention, the harmonic current and the power supply voltage fluctuation at the time of turning on and off the power supply are suppressed, and the influence of the harmonic current on other devices that obtain power from the same power supply is prevented. Becomes possible.

According to a fifth aspect of the present invention, there is provided an AC power supply means for supplying AC power, such as a commercial power supply.
Heating means including a resistor or a Peltier element, and temperature detection means for detecting the temperature of a load constituting the heating means,
When power is supplied to the heating means, the phase angle of the AC power supplied based on the temperature detected by the temperature detection means is set to approximately 0.
Control means for performing a soft start control in which the phase is increased at a first designated phase angle close to 0 ° and the phase angle is gradually increased at predetermined intervals until full lighting (phase angle of 180 °), and AC power supply means Rectifying and smoothing the supplied alternating current,
Rectifying / smoothing means including an active filter circuit or the like.

Therefore, according to the present invention, the rush power supply, harmonic current and power supply voltage fluctuation when the power supply is turned on are suppressed,
It is possible to prevent the influence of the harmonic current on other devices that obtain power from the same power supply.

According to a sixth aspect of the present invention, there is provided an AC power supply means for supplying AC power, such as a commercial power supply.
Heating means including a resistor or a Peltier element, and temperature detection means for detecting the temperature of a load constituting the heating means,
When power is supplied to the heating means, the phase angle of the AC power supplied based on the temperature detected by the temperature detection means is set to approximately 0.
When starting at a first designated phase angle close to ° and performing soft start control in which the phase angle is gradually increased at predetermined intervals until full lighting (phase angle of 180 °), power is cut off to the heating means. Control means for performing soft-stop control in which the phase angle is raised at a second designated phase angle close to approximately 180 °, and thereafter the phase angle is gradually reduced at predetermined intervals until all lights are turned off (phase angle 0 °). And a rectifying / smoothing unit configured by an active filter circuit or the like, which rectifies and smoothes the AC current supplied by the AC power supply unit.

Therefore, according to the present invention, the inrush power supply, the harmonic current, and the fluctuation of the power supply voltage at the time of turning on and off the power supply are suppressed, and the influence of the harmonic current on other devices that obtain power from the same power supply is suppressed. Can be prevented.

Further, according to the present invention, an AC power supply step of supplying AC power such as a commercial power supply,
A heating process including a resistor or a Peltier element, and a temperature detection process for detecting a temperature of a load included in the heating process;
A control step of limiting the phase angle of the AC power supplied based on the temperature detected in the temperature detection step to a designated phase angle when power is turned on or off in the heating step.

Therefore, according to the present invention, it is possible to suppress the harmonic current when the power is turned on and when the power is turned off, and to prevent the influence of the harmonic current on other devices that obtain power from the same power source. .

The invention according to claim 8 is an AC power supply step of supplying AC power such as a commercial power supply.
A heating process including a resistor or a Peltier element, and a temperature detection process for detecting a temperature of a load included in the heating process;
When power is supplied to the heating step, the phase angle of the AC power supplied based on the temperature detected in the temperature detecting step is substantially zero.
A soft start control in which the phase angle is increased at a first designated phase angle close to ° and the phase angle is gradually increased at every predetermined cycle until full lighting (phase angle of 180 °).

Therefore, according to the present invention, it is possible to suppress the inrush power supply and the harmonic current at the time of turning on the power supply, and to prevent the influence of the harmonic current on other devices that obtain power from the same power supply. .

Further, according to the ninth aspect of the present invention, there is provided an AC power supply step of supplying AC power, such as a commercial power supply.
A heating process including a resistor or a Peltier element, and a temperature detection process for detecting a temperature of a load included in the heating process;
When power is supplied to the heating step, the phase angle of the AC power supplied based on the temperature detected in the temperature detecting step is substantially zero.
When the power is cut off at the first designated phase angle close to ° and the power is cut off to the heating step by performing a soft start control in which the phase angle is gradually increased at predetermined intervals until all the lights are turned on (phase angle 180 °). A control step of raising the phase angle at a second designated phase angle close to approximately 180 °, and thereafter gradually reducing the phase angle at predetermined intervals until all lights are turned off (phase angle of 0 °). And

Therefore, according to the present invention, it is possible to suppress the rush power supply and the harmonic current at the time of turning on and off the power supply, and to prevent the influence of the harmonic current on other devices that obtain power from the same power supply. Becomes

Further, the invention according to claim 10 includes an AC power supply step of supplying AC power such as a commercial power supply, and a heating step including a resistor or a Peltier element.
A temperature detection step that detects the temperature of the load that constitutes the heating step, and a phase angle that specifies the phase angle of AC power supplied based on the temperature detected by the temperature detection step when power is turned on or off to the heating step. And a rectifying / smoothing step configured by an active filter circuit or the like for rectifying / smoothing the AC current supplied by the AC power supply step.

Therefore, according to the present invention, the harmonic current and the power supply voltage fluctuation at the time of turning on and off the power supply are suppressed, and the influence of the harmonic current on other devices that obtain power from the same power supply is prevented. Becomes possible.

The eleventh aspect of the present invention provides an AC power supply step of supplying AC power, such as a commercial power supply, and a heating step including a resistor or a Peltier element.
A temperature detection step of detecting a temperature of a load constituting the heating step; and, when power is supplied to the heating step, a phase angle of AC power supplied based on the temperature detected in the temperature detection step is substantially 0 °. A control step of performing a soft start control in which the phase angle is gradually increased every predetermined cycle until the lighting is started at a designated phase angle of 1 and a full lighting (phase angle of 180 °); A rectifying and smoothing step configured by an active filter circuit or the like for rectifying and smoothing the current.

Therefore, according to the present invention, the rush power supply, harmonic current and power supply voltage fluctuation when the power supply is turned on are suppressed,
It is possible to prevent the influence of the harmonic current on other devices that obtain power from the same power supply.

The invention according to claim 12 includes an AC power supply step of supplying AC power such as a commercial power supply, and a heating step including a resistor or a Peltier element.
A temperature detection step of detecting a temperature of a load constituting the heating step; and, when power is supplied to the heating step, a phase angle of AC power supplied based on the temperature detected in the temperature detection step is substantially 0 °. When the power is turned off to the heating step, a soft start control is performed in which the power is started at a designated phase angle of 1 and the phase angle is gradually increased at every predetermined cycle until all lights are turned on (phase angle of 180 °). A control step of performing soft-stop control in which the phase is started at a second designated phase angle close to about 180 ° and then gradually reduced at predetermined intervals until the lights are completely turned off (phase angle of 0 °); A rectifying / smoothing step configured by an active filter circuit or the like for rectifying / smoothing the alternating current supplied in the supplying step.

Therefore, according to the present invention, the inrush power supply, the harmonic current and the fluctuation of the power supply voltage at the time of turning on and off the power supply are suppressed, and the influence of the harmonic current on other devices that obtain power from the same power supply is suppressed. Can be prevented.

According to a thirteenth aspect of the present invention, there is provided a comparison process for comparing the temperature detected by the temperature detection unit with a stored reference temperature, and an AC supply to the heating unit based on the result of the comparison process when the power is turned on. A first control process of controlling the phase angle of the current to a predetermined phase angle, and a predetermined phase angle obtained by the first control process is changed to a predetermined phase angle slightly larger than the predetermined phase angle at predetermined intervals. A second control process for controlling, a third control process for repeating the first and second control processes until the phase angle becomes 180 °, and a phase angle of an alternating current supplied to the heating means when the power is turned off. A fourth control process for controlling to a predetermined phase angle, and a fifth control for controlling the predetermined phase angle obtained by the fourth control process to a predetermined phase angle slightly smaller than the predetermined phase angle at predetermined intervals. The control processing and the fourth to fifth control processing Storage medium that stores a program and data for executing a sixth control process repeated until the phase angle becomes 0 ° to the current control device.

Therefore, according to the present invention, the inrush power supply, the harmonic current, and the fluctuation of the power supply voltage at the time of turning on and off the power supply are suppressed, and the influence of the harmonic current on other devices that obtain power from the same power supply is suppressed. It is possible to realize a power supply control device that can prevent the occurrence of the power supply.

[0042]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a power supply control device, a power supply control method, and a storage medium storing a program and data according to the present invention will be described in detail with reference to the drawings.

First, in practicing the present invention, an active filter (also referred to as an active smoothing filter) circuit is used as rectifying and smoothing means in order to reduce a high-frequency current. FIG. 3 shows a circuit diagram of a power supply device equipped with a general active filter circuit.

The power supply device shown in FIG. 3 includes a diode bridge circuit 302 for full-wave rectifying a commercial power supply 301 which is an AC power supply.
This is a so-called two-converter type power supply device provided with an active filter circuit 310 and a DC-DC converter 320 at the subsequent stage. The active filter circuit 310 includes a choke coil 311, a diode 312, a capacitor 313, a first field-effect transistor 314 as a switching element, and a control circuit 315.

Further, the DC-DC converter 320 converts the ON / OFF of the transformer 321, the second field effect transistor 322 for switching the transformer 321, the output voltage detection circuit 323, and the second field effect transistor 322 into PWM. It comprises a control circuit 324 for controlling (pulse width modulation), diodes 325 and 326 for rectifying the current from the secondary winding of the transformer 321, a smoothing choke coil 327, and a smoothing capacitor 328.

According to such a power supply device equipped with a two-converter active filter circuit, the harmonic current is suppressed and the power factor is improved as compared with a capacitor input type switching regulator.

FIG. 4A shows an input current waveform of a power supply device equipped with a general active filter circuit, and FIG. 4B shows an input current waveform of a power supply device without an active filter circuit.

In FIG. 3, an AC voltage supplied from a commercial power supply 301 is rectified by a diode bridge circuit 302 to become a DC voltage. The rectified voltage is smoothed by the active filter circuit 310 and further smoothed by the DC-DC converter. With this circuit,
FIG. 4A shows the input current and the input voltage obtained from the AC power supply. FIG. 4B shows the current and the voltage input to the power supply device without the active filter circuit, and as is clear from these two figures, the power supply device without the active filter circuit. The current and the voltage inputted to are converted into a pulse shape, and thus include a harmonic current. On the other hand, the current and the voltage input to the power supply device equipped with the active filter circuit do not include the harmonic current because the shape at the time of input is maintained.

An embodiment in which a power supply control device, a power supply control method, and a storage medium storing a program and data according to the present invention are applied to an electrophotographic apparatus will be described in detail with reference to the drawings.

FIG. 5 is a block diagram showing the configuration of an embodiment in which the power supply control device according to the present invention is applied to an electrophotographic apparatus.

As a heater power supply 501 in FIG. 5, a commercial AC power supply is normally used.
02 is supplied with power. The switch 507 is configured by a switch capable of high-speed switching such as a semiconductor switching element transistor or SCR. The temperature of the heater 502 is detected by the temperature sensor 503 and the temperature detection circuit 504, and the resistance is calculated from the temperature of the heater 502 by the arithmetic circuit 505. The current supplied from the heater power supply 501 to the heater 502 does not exceed a preset value. Heater 50
Determine the control voltage to 2. The control circuit 506 generates a switching signal of the supply voltage to the heater 502 from the control voltage to the heater 502, and controls the switch 507 so that the supply voltage to the heater 502 does not exceed the control voltage.

Here, in FIG. 5, in order to reduce the inrush current to the heater 502, when the temperature of the heater 502 is high at the time of power supply (for example, at about 150 ° C. or more).
Since the inrush current to the heater 502 is large, the phase angle is substantially 0 ° as in the input current waveform example shown in FIG. 6A (vertical axis: applied voltage amount, horizontal axis: voltage application time) shown in FIG. At a specified phase angle of a ° close to
0 °), a soft start control is performed in which the phase angle is gradually increased every 1 Hz (for example, about 1 ° to 30 °). When the temperature of the heater 502 at the time of power supply is low (for example, about 0 ° C. to 150 ° C.), the phase angle is set to approximately 0 ° as in the input current waveform example shown in FIG. Start up at a specified phase angle of close a °, turn on all (phase angle 1
80 °) gradually (from 1 ° to longer than 1 Hz)
The soft start control for increasing the phase (about 30 ° at a time) is performed, and then the ON control is continued.

In the ON control, when the temperature detected by the temperature sensor 503 and the temperature detection circuit 504 rises to the designated temperature, the power supply to the heater 502 is stopped.

As described above, by performing the soft start-on control, it is possible to suppress the inrush voltage of the electrophotographic apparatus and suppress the fluctuation of the power supply voltage. Further, by mounting a power supply device having an active filter circuit and performing on-control after the fixing heater is fully turned on, it is possible to suppress the harmonic current of the electrophotographic apparatus.

In FIG. 3, an embodiment of the operation for performing the soft stop-off control in addition to the soft start-on control will be described in detail with reference to FIGS. 7 (a), (b) and (c). explain.

In FIG. 5, in order to reduce the inrush current to the heater 502, when the temperature of the heater 502 at the time of power supply is high (for example, about 150 ° C. or more), the inrush current to the heater 502 is large. FIG. 7A (vertical axis:
(Applied voltage amount, horizontal axis: voltage application time), the phase angle is raised at a specified phase angle of a ° close to 0 ° as in the input current waveform example shown in FIG. Up to 1H
Soft start control is performed in which the phase angle is gradually increased for each z (for example, about 1 ° to 30 °). Further, when the temperature of the heater 502 at the time of power supply is low (for example, 0 ° C
In the case of about 150 ° C.), as shown in the example of the input current waveform shown in FIG. °) gradually (in a cycle longer than 1 Hz, about 1 ° to 30 ° each)
The soft start control for increasing the phase is performed, and thereafter the ON control is continued.

In the ON control, after the temperature detected by the temperature sensor 503 and the temperature detection circuit 504 rises to the designated temperature, the phase angle is reduced to approximately 180 ° as in the input current waveform example shown in FIG. Start up at a specified phase angle of close z °,
Thereafter, soft stop control is performed to gradually reduce the phase angle every 1 Hz until the lights are completely turned off (the phase angle is 0 °), and after the lights are completely turned off, the off control is continued.

As described above, by performing the soft start-on control, the inrush time of the electrophotographic apparatus can be suppressed, and by performing the soft start-on control and the soft stop-off control, the power supply voltage fluctuation can be suppressed. . In addition, by mounting a power supply device having an active filter circuit, it is possible to suppress a harmonic current of the electrophotographic apparatus.

In FIG. 3, one embodiment of the operation for performing the soft start-on control will be described with specific numerical values.
This will be described in detail with reference to FIGS.

Here, in FIG. 3, in order to reduce the rush current to the heater 502, when the temperature of the heater 502 is low at the time of power supply (when the temperature is about 0 ° C. to 150 ° C.)
Since the rush current to the heater 502 is large, the phase angle is set to 15 ° as in the input current waveform example shown in FIG. 8A (vertical axis: applied voltage amount, horizontal axis: voltage application time). 30 °, 45 °,..., 16 every 2 Hz
By changing the phase angle to 5 °, a soft start control is performed in which the phase angle is increased until all the lights are turned on (the phase angle is 180 °). When the temperature of the heater 502 at the time of power supply is high (150 ° C. or more), the phase angle is raised at 15 ° as in the input current waveform example shown in FIG. °, 45
°, ..., 165 ° and all lighting (phase angle 1
Soft start control is performed to increase the phase angle up to 80 °), and thereafter, the ON control is continued.

In the ON control, when the temperature detected by the temperature sensor 503 and the temperature detection circuit 504 rises to the designated temperature, the power supply to the heater 502 is stopped.

As described above, by performing the soft start-on control, the inrush voltage of the electrophotographic apparatus can be suppressed, and the fluctuation of the power supply voltage can be suppressed. Further, by mounting a power supply device having an active filter circuit and performing on-control after the fixing heater is fully turned on, it is possible to suppress the harmonic current of the electrophotographic apparatus.

In FIG. 3, one embodiment of the operation for performing the soft stop-off control in addition to the soft start-on control is shown by specific numerical values.
This will be described in detail with reference to (b) and (c).

In FIG. 3, in order to reduce the rush current to the heater 502, when the temperature of the heater 502 at the time of power supply is low (from about 0 ° C. to about 150 ° C.), the rush current to the heater 502 is reduced. As shown in FIG. 9 (a) (vertical axis: applied voltage amount, horizontal axis: voltage application time), the phase angle rises at 15 ° as shown in FIG.
Soft start control is performed by changing the phase angle to 30 °, 45 °,..., 75 ° every 2 Hz and increasing the phase angle until all lighting (phase angle 180 °). In addition, when the temperature of the heater 502 at the time of power supply is high (150 ° C. or more), FIG.
As shown in the input current waveform example shown in FIG.
Start up at 1Hz, 30 °, 45 °, ...,
By changing it to 165 °, soft start control is performed to increase the phase angle until all lightings (phase angle: 180 °), and then ON control is continued.

In the ON control, after the temperature detected by the temperature sensor 503 and the temperature detection circuit 504 rises to the designated temperature, the phase angle is set to 165 ° as in the input current waveform example shown in FIG. 9C. Start-up, 150 °, 1Hz
By changing the angle to 35 °,..., 15 °, soft stop control is performed to reduce the phase angle until all lights are turned off (phase angle is 0 °).

As described above, it is possible to suppress the inrush time of the electrophotographic apparatus by performing the soft start on control, and to suppress the power supply voltage fluctuation by performing the soft start on control and the soft stop off control. . In addition, by mounting a power supply device having an active filter circuit, it is possible to suppress a harmonic current of the electrophotographic apparatus.

[0067]

Therefore, according to the present invention, according to the first aspect of the present invention, the rush power supply and the power supply voltage fluctuation at the time of turning on the power supply are suppressed, and the other equipment which obtains power from the same power supply can be used. Can be prevented from being affected by power supply voltage fluctuations.

According to the second aspect of the present invention, the inrush power supply and the power supply voltage fluctuation at the time of turning on the power supply are suppressed, and the influence of the power supply voltage fluctuation on other devices that obtain power from the same power supply is prevented. Becomes possible.

According to the third aspect of the present invention, the inrush power supply and the power supply voltage fluctuation at the time of turning on and off the power supply are suppressed, and the influence of the power supply voltage fluctuation on other devices that obtain power from the same power supply. Can be prevented.

According to the fourth aspect of the present invention, the harmonic current and the power supply voltage fluctuation at the time of turning on and off the power supply are suppressed, and the harmonic current to another device which obtains power from the same power supply is suppressed. Can be prevented.

According to the fifth aspect of the present invention, the inrush power supply, the harmonic current, and the power supply voltage fluctuation at the time of turning on the power supply are suppressed, and the harmonic current to another device which obtains power from the same power supply is suppressed. Can be prevented.

Further, according to the invention of claim 6, the rush power supply, the harmonic current and the fluctuation of the power supply voltage at the time of turning on and off the power supply are suppressed, and the harmonic power is supplied to another device which obtains power from the same power supply. The effect of the wave current can be prevented.

According to the seventh aspect of the present invention, the power supply voltage fluctuation at the time of turning on and off the power supply is suppressed, and the influence of the power supply voltage fluctuation on other devices that obtain power from the same power supply is prevented. Becomes possible.

Further, according to the present invention, the inrush power supply and the power supply voltage fluctuation at the time of turning on the power supply are suppressed, and the influence of the power supply voltage fluctuation on other devices that obtain power from the same power supply is prevented. Becomes possible.

According to the ninth aspect of the present invention, the inrush power supply and the power supply voltage fluctuation at the time of turning on and off the power supply are suppressed, and the influence of the power supply voltage fluctuation on other devices that obtain power from the same power supply. Can be prevented.

According to the tenth aspect of the present invention, the harmonic current and the power supply voltage fluctuation at the time of turning on and off the power supply are suppressed, and the harmonic current to another device which obtains power from the same power supply is suppressed. Can be prevented.

According to the eleventh aspect of the present invention, the inrush power supply, the harmonic current, and the power supply voltage fluctuation at the time of turning on the power supply are suppressed, and the harmonic current to another device that obtains power from the same power supply is suppressed. Can be prevented.

According to the twelfth aspect of the present invention, the rush power supply, the harmonic current, and the fluctuation of the power supply voltage at the time of turning on and off the power supply are suppressed, and the harmonic power supply to other equipment which obtains power from the same power supply is suppressed. The effect of the wave current can be prevented.

According to the thirteenth aspect of the present invention, the rush power supply, the harmonic current and the fluctuation of the power supply voltage at the time of turning on and off the power supply are suppressed, and the higher power supply to other equipment which obtains power from the same power supply is suppressed. It is possible to realize a power supply control device capable of preventing the influence of the wave current.

[Brief description of the drawings]

FIG. 1 is a circuit diagram example of a capacitor input type rectifier circuit.

FIG. 2 is a waveform of each part of the capacitor input type rectifier circuit of FIG.

FIG. 3 is a circuit diagram of a power supply device equipped with a general active filter circuit.

FIG. 4A is an input current waveform of a power supply device equipped with a general active filter circuit. (B) is an input current waveform of the power supply device without the active filter circuit.

FIG. 5 is a block diagram of an electrophotographic apparatus according to the present invention.

FIG. 6A is an embodiment of a current waveform input to a fixing heater by an operation of performing soft start-on control when a fixing heater temperature of an electrophotographic apparatus to which a power supply control device according to the present invention is applied is low. It is. (6) is an embodiment of the current waveform input to the fixing heater by the operation of performing the soft start-on control when the fixing heater temperature of the electrophotographic apparatus to which the power supply control device according to the present invention is applied is high.

FIG. 7A is an embodiment of a current waveform input to a fixing heater by an operation of performing a soft start-on control when a fixing heater temperature of an electrophotographic apparatus to which a power supply control device according to the present invention is applied is low. It is. (B) is an embodiment of the current waveform input to the fixing heater by the operation of performing the soft start-on control when the fixing heater temperature of the electrophotographic apparatus to which the power supply control device according to the present invention is applied is high. (C) shows an operation of performing soft stop-off control of an electrophotographic apparatus to which the power supply control device according to the present invention is applied,
5 is an embodiment of a current waveform input to a fixing heater.

FIG. 8A shows a specific example of a current waveform input to a fixing heater by an operation of performing soft start-on control when a fixing heater temperature of an electrophotographic apparatus to which a power supply control device according to the present invention is applied is low. It is an embodiment using a numerical example. (B) uses a specific numerical example of a current waveform input to the fixing heater by an operation of performing soft start-on control when the fixing heater temperature of the electrophotographic apparatus to which the power supply control device according to the present invention is applied is high. This is one embodiment.

FIG. 9A shows a specific example of a current waveform input to the fixing heater by an operation of performing soft start-on control when the fixing heater temperature of the electrophotographic apparatus to which the power supply control device according to the present invention is applied is low. It is an embodiment using a numerical example. (B) uses a specific numerical example of a current waveform input to the fixing heater by an operation of performing soft start-on control when the fixing heater temperature of the electrophotographic apparatus to which the power supply control device according to the present invention is applied is high. This is one embodiment.
(C) is an embodiment using a specific numerical example of a current waveform input to the fixing heater by an operation of performing soft stop-off control of an electrophotographic apparatus to which the power supply control device according to the present invention is applied.

[Explanation of symbols]

 Reference Signs List 100 AC power supply 101 Input power supply 102 Input current 110 Diode 120 Capacitor 121 Capacitor voltage 130 Load 301 Commercial power supply 302 Diode bridge circuit 310 Active filter circuit 311 Choke coil 312 Diode 313 Capacitor 314 First field effect transistor 315 Control circuit 320 DC-DC converter 321 Transformer 322 Second field effect transistor 323 Output voltage detection circuit 324 Control circuit 325 Diode 326 Diode 327 Smooth choke coil 328 Smoothing capacitor 501 Heater power supply 502 Heater 503 Temperature sensor 504 Temperature detection circuit 505 Operation circuit 506 Control circuit 507 Switch

──────────────────────────────────────────────────の Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) H02J 1/00 309 H02J 1/00 309R 5H006 1/02 1/02 5H420 H02M 3/28 H02M 3/28 H 5H730 H05B 3/00 310 H05B 3/00 310D 310C 310Z // H02M 7/12 H02M 7/12 PF term (reference) 2H027 DA12 EA15 EC20 ED25 EE07 EF06 EF09 JA20 JB30 JC08 JC16 ZA01 2H033 AA41 CA25 CA27 CA20 3K058 AA46 BA00 CA23 CB04 CB06 CB30 CD01 5G065 AA05 BA04 DA06 DA08 HA04 HA14 LA01 LA07 5G066 LA04 5H006 AA02 CA02 CA07 CA12 CB01 CB07 CB08 CC02 DA02 DA04 DC05 GA02 GA04 5H420 BB02 BB13 EB03 EB03 EB03 EB03 EB03 EB03 EB03 EB03 EB14 EB03 EB14 EB03 EB03 EB14 NE06 5H730 AS01 AS12 BB14 BB23 BB57 BB86 CC03 CC04 DD04 EE08 FD01 FG01 FG2 5 XC04 XC09

Claims (13)

[Claims] 1. An AC power supply unit for supplying AC power, such as a commercial power supply, a heating unit including a resistor or a Peltier element, and a temperature detection unit for detecting a temperature of a load constituting the heating unit. Means for controlling the phase angle of AC power supplied based on the temperature detected by the temperature detecting means when power is turned on or off to the heating means, to a specified phase angle; A power supply control apparatus characterized in that power supply voltage fluctuations during power-on and power-off are suppressed, and that the influence of power supply voltage fluctuations on other devices that obtain power from the same power supply can be prevented. 2. An AC power supply unit for supplying AC power, such as a commercial power supply, a heating unit including a resistor or a Peltier element, and a temperature detection unit for detecting a temperature of a load constituting the heating unit. Means, when power is supplied to the heating means, a phase angle of AC power supplied based on the temperature detected by the temperature detection means is started at a first designated phase angle close to substantially 0 °, and Control means for performing soft start control in which the phase angle is gradually increased at predetermined intervals until lighting (a phase angle of 180 °);
A power supply control device capable of preventing the influence of power supply voltage fluctuation on other devices that obtain power from the same power supply. 3. An AC power supply unit such as a commercial power supply for supplying AC power, a heating unit including a resistor or a Peltier element, and a temperature detection unit for detecting a temperature of a load constituting the heating unit. Means, when power is supplied to the heating means, a phase angle of AC power supplied based on the temperature detected by the temperature detection means is started at a first designated phase angle close to substantially 0 °, and A soft start control is performed in which the phase angle is gradually increased at predetermined intervals until lighting (a phase angle of 180 °), and when the power is cut off to the heating means, a second phase angle close to approximately 180 ° is set.
At the specified phase angle, and then turn off all (phase angle 0
And a control means for performing a soft stop control that gradually reduces the phase angle at predetermined intervals up to the predetermined power cycle until the power supply is turned on and off. A power supply control device capable of preventing the influence of power supply voltage fluctuations on other devices obtained. 4. An AC power supply unit for supplying AC power, such as a commercial power supply, a heating unit including a resistor or a Peltier element, and a temperature detection unit for detecting a temperature of a load constituting the heating unit. Means for controlling the phase angle of AC power supplied based on the temperature detected by the temperature detecting means when power is supplied or cut off to the heating means, to the specified phase angle; and Means for rectifying and smoothing the alternating current supplied by the means, comprising rectifying and smoothing means constituted by an active filter circuit, etc., to suppress harmonic currents and power supply voltage fluctuations at power-on and power-off, and A power supply control device capable of preventing the influence of a harmonic current on another device that obtains power from a power supply. 5. An AC power supply unit for supplying AC power, such as a commercial power supply, a heating unit including a resistor or a Peltier element, and a temperature detection unit for detecting a temperature of a load constituting the heating unit. Means, when power is supplied to the heating means, a phase angle of AC power supplied based on the temperature detected by the temperature detection means is started at a first designated phase angle close to substantially 0 °, and Control means for performing soft start control in which a phase angle is gradually increased at predetermined intervals until lighting (a phase angle of 180 °); and an active filter circuit for rectifying and smoothing an alternating current supplied by the alternating current power supply means. Rectifying / smoothing means configured to reduce inrush power when power is turned on, harmonic current and power supply voltage fluctuation, and reduce harmonic current to other equipment that is obtaining power from the same power supply. Yo A power control device characterized in that the power control device can prevent the influence of the power supply. 6. An AC power supply unit for supplying AC power, such as a commercial power supply, a heating unit including a resistor or a Peltier element, and a temperature detection unit for detecting a temperature of a load constituting the heating unit. Means, when power is supplied to the heating means, a phase angle of AC power supplied based on the temperature detected by the temperature detection means is started at a first designated phase angle close to substantially 0 °, and A soft start control is performed in which the phase angle is gradually increased at predetermined intervals until lighting (a phase angle of 180 °), and when the power is cut off to the heating means, a second phase angle close to approximately 180 ° is set.
At the specified phase angle, and then turn off all (phase angle 0
°), control means for performing a soft stop control that gradually reduces the phase angle at predetermined intervals up to a predetermined cycle, and an active filter circuit for rectifying and smoothing the AC current supplied by the AC power supply means. It has rectifying and smoothing means, suppresses inrush power, harmonic current and power supply voltage fluctuations when power is turned on and off, and prevents the influence of harmonic current on other devices that obtain power from the same power source. A power supply control device characterized in that: 7. An AC power supply step for supplying AC power such as a commercial power supply, a heating step including a resistor or a Peltier element, and a temperature detection for detecting a temperature of a load constituting the heating step. And a control step of limiting the phase angle of the AC power supplied based on the temperature detected by the temperature detection step to a specified phase angle when turning on or off the power to the heating step. A power supply control method characterized in that power supply voltage fluctuations during power-on and power-off are suppressed, and the effect of power supply voltage fluctuations on other devices that are receiving power from the same power supply can be prevented. 8. An AC power supply step for supplying AC power such as a commercial power supply, a heating step including a resistor or a Peltier element, and a temperature detection for detecting a temperature of a load constituting the heating step. When power is supplied to the heating step, the phase angle of the AC power supplied based on the temperature detected in the temperature detection step is started at a first designated phase angle close to substantially 0 °, and A control step of performing a soft start control in which a phase angle is gradually increased at predetermined intervals until lighting (a phase angle of 180 °);
A power supply control method characterized in that it is possible to prevent the influence of power supply voltage fluctuation on other devices that obtain power from the same power supply. 9. An AC power supply step for supplying AC power such as a commercial power supply, a heating step including a resistor or a Peltier element, and a temperature detection for detecting a temperature of a load constituting the heating step. When power is supplied to the heating step, the phase angle of the AC power supplied based on the temperature detected in the temperature detection step is started at a first designated phase angle close to substantially 0 °, and A soft start control is performed in which the phase angle is gradually increased at predetermined intervals until lighting (a phase angle of 180 °). When the power is cut off to the heating step, the second phase angle is set to a value close to 180 °.
At the specified phase angle, and then turn off all (phase angle 0
And a control step of performing a soft stop control that gradually reduces the phase angle at predetermined intervals up to °), suppresses inrush power and power supply voltage fluctuations at power-on and power-off, and controls power from the same power supply. A power supply control method characterized in that it is possible to prevent the influence of power supply voltage fluctuations on other devices obtained. 10. An AC power supply step for supplying AC power such as a commercial power supply, a heating step including a resistor or a Peltier element, and a temperature detection for detecting a temperature of a load constituting the heating step. A step of controlling the phase angle of the AC power supplied based on the temperature detected by the temperature detection step to a specified phase angle when turning on or off the power to the heating step; and Rectifying and smoothing the alternating current supplied by the process, comprising a rectifying and smoothing step configured by an active filter circuit, etc., to suppress harmonic currents and power supply voltage fluctuations at power-on and power-off, and A power supply control method characterized in that it is possible to prevent the influence of a harmonic current on other devices that obtain power from a power supply. 11. An AC power supply step for supplying AC power such as a commercial power supply, a heating step including a resistor or a Peltier element, and a temperature detection for detecting a temperature of a load constituting the heating step. When power is supplied to the heating step, the phase angle of the AC power supplied based on the temperature detected in the temperature detection step is started at a first specified phase angle close to substantially 0 °, and A control step of performing a soft start control in which a phase angle is gradually increased at predetermined intervals until lighting (a phase angle of 180 °); and an active filter circuit for rectifying and smoothing an AC current supplied in the AC power supply step. Rectifying and smoothing process, which is composed of a power supply, suppresses inrush power supply, harmonic currents and power supply voltage fluctuations, and reduces harmonic currents to other equipment that obtains power from the same power supply. A power supply control method characterized in that it is possible to prevent the influence of the power supply. 12. An AC power supply step for supplying AC power such as a commercial power supply, a heating step including a resistor or a Peltier element, and a temperature detection for detecting a temperature of a load constituting the heating step. When power is supplied to the heating step, the phase angle of the AC power supplied based on the temperature detected in the temperature detection step is started at a first designated phase angle close to substantially 0 °, and A soft start control is performed in which the phase angle is gradually increased at predetermined intervals until lighting (a phase angle of 180 °). When the power is cut off to the heating step, the second phase angle is set to a value close to 180 °.
At the specified phase angle, and then turn off all (phase angle 0
°), a control step of performing a soft stop control in which the phase angle is gradually reduced at predetermined intervals up to a predetermined cycle, and an active filter circuit for rectifying and smoothing the AC current supplied in the AC power supply step. It has a rectifying and smoothing process and suppresses inrush power, harmonic current and power supply voltage fluctuations when power is turned on and off, and prevents the effects of harmonic current on other devices that are receiving power from the same power source. A power supply control method characterized in that: 13. A comparison process for comparing a temperature detected by the temperature detection unit with a stored reference temperature, and, when power is turned on, a phase angle of an alternating current supplied to the heating unit based on a result of the comparison process. A first control process for controlling to a phase angle; and a second control for controlling the predetermined phase angle obtained by the first control process to a predetermined phase angle slightly larger than the predetermined phase angle at predetermined intervals. And a third control process in which the first and second control processes are repeated until the phase angle becomes 180 °. When the power is turned off, the phase angle of the alternating current supplied to the heating means is set to a predetermined phase. A fourth control process of controlling the angle to be an angle; and a fifth control of controlling the predetermined phase angle obtained by the fourth control process to a predetermined phase angle slightly smaller than the predetermined phase angle at predetermined intervals. A control process; The control process, sixth storage a storage medium a program and data for executing the control process to the current control device of repeating until the phase angle becomes 0 °.