JP4644959B2 - Power supply - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a power supply apparatus that receives a commercial AC voltage and uses a power factor correction circuit to obtain a predetermined DC voltage.
[0002]
[Prior art]
Conventionally, a power supply device as shown in FIG. 5 has been proposed in which a commercial AC voltage is input and a power factor correction circuit is used to obtain a predetermined DC voltage.
[0003]
The conventional power supply device of FIG. 5 will be described. In FIG. 5, reference numeral 1 denotes a power plug to which a commercial AC voltage of, for example, 100 V is supplied. One end of the power plug 1 is a fuse 2 and a high frequency blocking filter 3 is used. Is connected to one input terminal 4a of the full-wave rectifier circuit 4 and the other end of the power plug 1 is connected to the other input terminal 4b of the full-wave rectifier circuit 4 via a filter 3 for blocking high frequency. To do.
[0004]
A power factor correction circuit (PFC (Power Factor Correction)) is connected via a resistor 5 for preventing an inrush current generated when a smoothing capacitor described later is not charged at the positive voltage output terminal 4c of the full-wave rectifier circuit 4. Circuit) 6 and a relay 7 including a connection switch 7a and an electromagnetic device 7b is connected in parallel to the resistor 5 for preventing inrush current. The negative voltage output terminal 4 d of the full wave rectifier circuit 4 is connected to the other input terminal 6 b of the PFC circuit 6.
[0005]
The PFC circuit 6 is a boost converter that corrects an AC input current in a sine wave shape to increase the power factor and obtains, for example, a DC voltage of 390 V boosted to its output terminals 6c and 6d.
[0006]
The PFC circuit 6 will be described. One input terminal 6a of the PFC circuit 6 is connected to one output terminal 6c through a series circuit of a boosting coil 6e and a rectifying diode 6f, and the coil 6e and The connection point of the diode 6f is connected to the drain of the field effect transistor 6g constituting the switching element, the source of the field effect transistor 6g is grounded, and the gate of the field effect transistor 6g is connected to the output terminals 6c and 6d of the PFC circuit 6. For example, it is connected to a switching signal output terminal OUT of a control IC (integrated circuit) 6h for obtaining a DC voltage of 390V. The connection point between the diode 6f and one output terminal 6c is grounded through a smoothing capacitor 6i.
[0007]
The other input terminal 6b of the PFC circuit 6 is connected to the other output terminal 6d of the PFC circuit 6 via a resistor 6j for current detection, and the other output terminal 6d is grounded. The positive voltage output terminal 4c of the full-wave rectifier circuit 4 is connected via a resistor 8 to an input terminal IAC to which an input signal for making the AC input current of the control IC 6h a sine wave is supplied.
[0008]
The output voltage obtained at the output terminal 6c of the PFC circuit 6 is supplied to the output voltage input terminal VS of the control IC 6h. In addition, one input terminal 4a of the full-wave rectifier circuit 4 is connected to the anode of the diode 9, and the other input terminal 4b of the full-wave rectifier circuit 4 is connected to the anode of the diode 10. Each cathode is connected to each other.
[0009]
The connection points of the cathodes of the diodes 9 and 10 are grounded through, for example, a series circuit of four resistors 11, 12, 13 and 14, and the connection points of the resistors 13 and 14 are compared with a voltage detection comparison circuit. Is connected to the non-inverting input terminal + of the operational amplifier circuit 15 constituting the circuit, and the connection point of the resistors 13 and 14 is grounded via the smoothing capacitor 16, and the inverting input terminal-of the operational amplifier circuit 15 is used as a reference. It is grounded through a reference voltage element 17 from which a voltage is obtained.
[0010]
The operational amplifier circuit 15 constituting this voltage detection comparator circuit detects an alternating current (AC) voltage obtained between one and the other input terminals 4a and 4b of the full-wave rectifier circuit 4, and this one and the other As shown in FIG. 6C, for example, when an AC voltage of AC 70 V or higher is obtained between the input terminals 4a and 4b, the output side of the operational amplifier circuit 15 is configured to obtain a high level “1”.
[0011]
The control IC 6h is turned on / off by the output signal of the operational amplifier circuit 15. That is, when the output signal of the operational amplifier circuit 15 becomes high level “1”, the control IC 6h is set in an operating state. When the output signal of the operational amplifier circuit 15 is low level “0”, the control IC 6h is activated. The IC 6h is set to an inoperative state.
[0012]
Also, one output terminal 6c of the PFC circuit 6 is grounded through a series circuit of four resistors 18, 19, 20, and 21, for example, and the connection point of the resistors 20 and 21 constitutes a voltage detection comparison circuit. Is connected to the non-inverting input terminal + of the operational amplifier circuit 22 and the connection point of the resistors 20 and 21 is grounded via the smoothing capacitor 23, and the reference voltage is applied to the inverting input terminal-of the operational amplifier circuit 15. The obtained reference voltage element 24 is grounded.
[0013]
The operational amplifier circuit 22 constituting the voltage detection comparator circuit detects the direct current (DC) output voltage obtained at the output terminals 6c and 6d of the PFC circuit 6, and the output terminals 6c and 6d are connected to FIG. As shown in FIG. 6D, when a DC voltage of, for example, DC 350 V or higher is obtained, a high level “1” is obtained on the output side of the operational amplifier circuit 22.
[0014]
The output signal of the operational amplifier circuit 22 is supplied to one input terminal of a NAND circuit 25 that controls the relay 7, and the output signal of the operational amplifier circuit 15 is supplied to the other input terminal of the NAND circuit 25. When the output side of the NAND circuit 25 becomes low level “0”, a current is supplied to the electromagnetic device 7b of the relay 7 to turn on the connection switch 7a.
[0015]
For example, a DC voltage of DC 390 V obtained at one and the other output terminals 6 c and 6 d of the PFC circuit 6 is supplied to the main converter circuit 26, and the DC voltage obtained at the output terminals 26 a and 26 b of the main converter circuit 26 is supplied to the main device. Supply as (set) power. The main converter circuit 26 is, for example, an insulating flyback converter circuit, and converts the DC side voltage of 390V to a DC voltage used by the secondary side main unit (set) or the like, for example, DC12V.
[0016]
The DC voltage obtained at the output terminals 6c and 6d of the PFC circuit 6 is supplied to the auxiliary power supply circuit 27 that supplies power to the primary side control circuit and the secondary side control circuit of the main converter 26. .
[0017]
The auxiliary power circuit 27 is composed of a switching type constant voltage circuit controlled by a pulse width modulation control integrated circuit (PWM control IC) 27a. One output terminal 6c of the PFC circuit 6 is connected to a starting resistor 27b. Is connected to the power supply terminal Vcc to which the operating voltage of the PWM control IC 27a is supplied, and this one output terminal 6c is connected to the field effect transistor 27c constituting the switching element via the primary winding 28a of the transformer 28. The PWM control IC 27a is connected to the drain, the source of the field effect transistor 27c is grounded, and the gate of the field effect transistor 27c is pulse-modulated in accordance with the output voltage of the auxiliary power circuit 27. To the output terminal OUT.
[0018]
An AC signal obtained from the secondary winding 28b of the transformer 28 is supplied to the rectifier circuit 29, and a DC voltage obtained from the output terminals 29a and 29b of the rectifier circuit 29 is used as a power source for a control circuit such as a main device (set). As used.
[0019]
One end of the tertiary winding 28c of the transformer 28 is connected to the power supply terminal Vcc for supplying the operating voltage of the control IC 6h via the rectifying diode 27d, and the output voltage of the auxiliary power circuit 27 of the PWM control IC 27a is used. Connected to an output voltage input terminal VS for supplying a corresponding voltage. The other end of the tertiary winding 28c is grounded. A connection point between the diode 27d and the output voltage input terminal VS of the PWM control IC 27a is grounded through a smoothing capacitor 27e.
[0020]
The connection point between the diode 27d and the capacitor 27e is connected to the power supply terminal Vcc of the PWM control IC 27a through the backflow prevention diode 27f, and the connection point between the diode 27f and the power supply terminal Vcc of the PWM control IC 27a is used for smoothing. Is grounded through a capacitor 27g. The connection point of the diode 27d and the capacitor 27e is connected to the output side of the NAND circuit 25 through the electromagnetic device 7b of the relay 7.
[0021]
In such a conventional power supply apparatus, when a commercial power supply of AC 100V is supplied to the power plug 1 as shown in FIG. 6A and the AC voltage between the input terminals 4a and 4b of the full-wave rectifier circuit 4 becomes 70V, for example, the AC voltage As shown in FIG. 6C, the output side of the detection operational amplifier circuit 15 becomes high level “1”. At this time, the control IC 6h of the PFC circuit 6 is in an operating state, controls the PFC circuit 6, and outputs the output voltage of the PFC circuit 6. 6B rises (the PWM control IC 27a of the auxiliary power supply circuit 27 is activated before the AC voltage reaches 70V, and the auxiliary power supply circuit 27 is also in an operating state). At this time, until the relay 7 operates, the inrush preventing resistor 5 is inserted to prevent the inrush current.
[0022]
When the PFC circuit 6 is in an operating state, the output voltage obtained at the output terminals 6c and 6d of the PFC circuit 6 rises as shown in FIG. 6B. When the output voltage of the output terminals 6c and 6d becomes, for example, DC 350V, the output side of the operational amplifier circuit 22 for detecting the output voltage becomes high level “1” as shown in FIG. 6D, and the output side of the NAND circuit 25 is illustrated. Since the low level is set to "0" as shown in 6E, a current flows through the electromagnetic device 7b of the relay 7 so that the connection switch 7a is turned on. When AC100V commercial power is continuously supplied to the power plug 1, this state is continued and predetermined power is continuously supplied to the main device (set) or the like.
[0023]
When the power supply is turned off and supply of AC 100V commercial power to the power plug 1 is stopped, the output side of the AC voltage detection operational amplifier circuit 15 becomes low level “0” as shown in FIG. 6C, and the control IC 6h of the PFC circuit 6 Becomes inoperative, and the output voltage of the output terminals 6c and 6d of the PFC circuit 6 decreases as shown in FIG. 6B. When this becomes, for example, DC 350 V or less, the output side of the operational amplifier circuit 22 for detecting the output voltage is shown in FIG. As shown in FIG. 6E, the output side of the NAND circuit 25 becomes low level “0” and the output level of the NAND circuit 25 becomes high level “1” as shown in FIG. 6E, so that no current flows through the electromagnetic device 7b of the relay 7, and the connection switch 7a of the relay 7 is turned off to prevent current. For this reason, the output voltage of the output terminals 6c and 6d of the PFC circuit 6 becomes zero as shown in FIG. 6B.
[0024]
[Problems to be solved by the invention]
However, in this conventional power supply device, an AC voltage detection circuit comprising an operational amplifier circuit 15, resistors 11, 12, 13, 14, a capacitor 16 and a reference voltage element 17 for a reference voltage, an operational amplifier circuit 22, a NAND circuit 25, The output voltage detection circuit of the output terminals 6c and 6d of the PFC circuit 6 including the resistors 18, 19, 20, and 21, the capacitor 23, and the reference voltage 24 has a large number of elements and a complicated configuration, and variation in each element. There was an inconvenience that adjustment by was difficult.
[0025]
Furthermore, in the AC voltage detection circuit, considering the world's commercial power supply, when this voltage is detected corresponding to various voltages between AC100V and AC240V, the number of elements of the AC voltage detection circuit increases. There is a disadvantage that the adjustment becomes difficult.
[0026]
Further, in this AC voltage detection circuit, an analog both-wave rectified signal from the diodes 9 and 10 and the like is supplied as a comparison signal to the operational amplifier circuit 15, so that this both-wave rectified signal has a voltage value and noise. Etc. is mixed, the output side of the operational amplifier circuit 15 repeats the high level “1” and the low level “0”, the relay 7 may cause chattering, and the operating state of the control IC 6h of the PFC circuit 6 There is a risk of inconvenience of repeating the inoperative state.
[0027]
Further, when the AC voltage detection circuit and the output voltage detection circuit are not properly adjusted and malfunctioned, the relay 7 is malfunctioned, and the main converter 26 operates to power the main device (set). However, there is an inconvenience that an inrush current flows and the resistor or the like is burned out.
[0028]
SUMMARY OF THE INVENTION The present invention has been made in view of the above points, and an object of the present invention is to prevent malfunctions without adjusting variations in each element of the AC voltage detection circuit and the output voltage detection circuit.
[0029]
[Means for Solving the Problems]
The power supply device of the present invention Input to the commercial AC voltage input terminal Commercial AC voltage The Uses power factor correction circuit Where Constant DC voltage Convert to In power supply, When supplying a commercial AC voltage input terminal to the commercial AC voltage input terminal, a resistor for preventing an inrush current provided in the previous stage of the power factor correction circuit, a relay connected in parallel to the resistor, and a predetermined reference AC voltage A detection reference AC voltage value detected at a voltage detection point, a predetermined first reference output voltage, and a second reference output voltage larger than the first reference output voltage are supplied to the output terminal of the power factor correction circuit. The first detection reference output voltage value and the second detection reference output voltage value detected at the output voltage detection point of the power factor correction circuit are stored in advance. Non-volatile memory; The commercial AC voltage and the output voltage of the power factor correction circuit are detected, and based on the detected commercial AC voltage, the output voltage of the power factor correction circuit, and each value stored in the nonvolatile memory, the power A microcontroller for controlling the rate correction circuit and the relay, and the microcontroller operates the power factor correction circuit when the detected commercial AC voltage becomes equal to or higher than the detection reference AC voltage value. When the detected output voltage of the power factor correction circuit becomes equal to or higher than the second detection reference output voltage value, the relay is turned on, the supply of the commercial AC voltage is stopped, and the detected commercial AC voltage becomes the detection reference. Even when the voltage value is smaller than the AC voltage value, the relay does not operate while the detected output voltage of the power factor correction circuit is larger than the first detection reference output voltage value. Keep on Is.
[0030]
According to the present invention, the reference AC voltage is supplied in advance to the commercial AC voltage input terminal and the reference output voltage is supplied to the output terminal of the power factor correction circuit, respectively, and the commercial AC voltage detection point and the output voltage detection of the power factor correction circuit are detected. The detection reference AC voltage value and the detection reference output voltage value obtained at the point are stored in a nonvolatile memory, and the detection reference AC voltage value and the detection reference output voltage value stored in the nonvolatile memory at the time of actual use are stored. It is used to detect the commercial AC voltage and the output voltage of the power factor correction circuit, and the detection reference AC voltage value and the detection reference output voltage value are values including variations of elements, and any adjustments are made. Without using the detection reference AC voltage value and the detection reference output voltage value, the AC voltage in the actual operation and the output voltage of the output terminal of the power factor correction circuit can be accurately detected. Can be, is not that cause a malfunction.
[0031]
Further, according to the present invention, the commercial AC voltage and the output voltage of the power factor correction circuit are detected by digital processing using the detection standard AC voltage value and the detection standard output voltage value stored in the nonvolatile memory during actual use. Since the relay and the control IC are controlled, chattering does not occur, and the operation state and the non-operation state are not repeated in a short period of time, so that the operation can be performed satisfactorily.
[0032]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an example of an embodiment of the power supply device of the present invention will be described with reference to FIGS. In the example of FIG. 1, parts corresponding to those in FIG.
[0033]
In the example of FIG. 1, reference numeral 1 denotes a power plug to which a commercial AC voltage of, for example, 100 V is supplied. One end of the power plug 1 is connected to one of the full-wave rectifier circuits 4 via a fuse 2 and a high frequency blocking filter 3. In addition to being connected to the input terminal 4a, the other end of the power plug 1 is connected to the other input terminal 4b of the full-wave rectifier circuit 4 through a high frequency blocking filter 3.
[0034]
The power factor correction circuit (PFC (Power Factor Correction) is connected to the positive voltage output terminal 4c of the full-wave rectifier circuit 4 through a resistor 5 for preventing an inrush current generated when a smoothing capacitor 6i described later is not charged. ) A circuit 7 is connected to one input terminal 6a of the circuit 6, and a relay 7 comprising a connection switch 7a and an electromagnetic device 7b is connected in parallel to the resistor 5 for preventing inrush current. The negative voltage output terminal 4 d of the full wave rectifier circuit 4 is connected to the other input terminal 6 b of the PFC circuit 6.
[0035]
The PFC circuit 6 is a boost converter that corrects an AC input current in a sine wave form to correct a power factor, and obtains, for example, a DC voltage of 390 V boosted at its output terminals 6c and 6d.
[0036]
The PFC circuit 6 will be described. One input terminal 6a of the PFC circuit 6 is connected to one output terminal 6c through a series circuit of a boosting coil 6e and a rectifying diode 6f, and the coil 6e and The connection point of the diode 6f is connected to the drain of the field effect transistor 6g constituting the switching element, the source of the field effect transistor 6g is grounded, and the gate of the field effect transistor 6g is connected to the output terminals 6c and 6d of the PFC circuit 6. For example, it is connected to a switching signal output terminal OUT of a control IC (integrated circuit) 6h for obtaining a DC voltage of 390V. The connection point between the diode 6f and one output terminal 6c is grounded through a smoothing capacitor 6i.
[0037]
The other input terminal 6b of the PFC circuit 6 is connected to the other output terminal 6d of the PFC circuit 6 via a resistor 6j for current detection, and the other output terminal 6d is grounded. The positive voltage output terminal 4c of the full-wave rectifier circuit 4 is connected via a resistor 8 to an input terminal IAC to which an input signal for making the AC input current of the control IC 6h a sine wave is supplied.
[0038]
The output voltage obtained at the output terminal 6c of the PFC circuit 6 is supplied to the output voltage input terminal VS of the control IC 6h. In addition, one input terminal 4a of the full-wave rectifier circuit 4 is connected to the anode of the diode 9, and the other input terminal 4b of the full-wave rectifier circuit 4 is connected to the anode of the diode 10. Each cathode is connected to each other.
[0039]
The connection points of the cathodes of the diodes 9 and 10 are grounded through, for example, a series circuit of four resistors 11, 12, 13 and 14. In this example, the connection points of the resistors 13 and 14 are obtained. AC voltage detection terminal V of 1-chip microcontroller 30 _AC The analog signal is supplied to a central control unit (CPU) through an A / D converter that converts the signal into a digital signal. In this case, the AD converter may be externally attached. This one-chip microcontroller 30 is configured in the same manner as in the prior art. The connection point between the resistors 13 and 14 is grounded through a smoothing capacitor 16. This one-chip microcontroller 30 has this AC voltage detection terminal V _AC 2 is used to detect an alternating current (AC) voltage between one and the other input terminals 4a and 4b of the full-wave rectifier circuit 4 obtained as shown in FIG. When the above AC voltage is obtained, a high level “1” is obtained at the output terminal PF of the one-chip microcontroller 30.
[0040]
The control IC 6h is turned on / off by an output signal obtained at the output terminal PF of the one-chip microcontroller 30. That is, when the output signal of the output terminal PF of the one-chip microcontroller 30 becomes high level “1”, the control IC 6h is activated, and the output signal of the output terminal PF of the one-chip microcontroller 30 is low level. When it is “0”, the control IC 6h is set in a non-operating state.
[0041]
Further, one output terminal 6c of the PFC circuit 6 is grounded through a series circuit of four resistors 18, 19, 20, and 21, for example, and the voltage obtained at the connection point of the resistors 20 and 21 is connected to the one-chip micro-chip. Output voltage detection terminal V of controller 30 _P The analog signal is supplied to the CPU through an AD converter that converts the analog signal into a digital signal. In this case, the A-D converter may be externally attached. The connection point between the resistors 20 and 21 is grounded through a smoothing capacitor 23.
[0042]
The one-chip microcontroller 30 detects a direct current (DC) output voltage obtained at the output terminals 6c and 6d of the PFC circuit 6, and the output terminals 6c and 6d rise to, for example, DC 370 V or more at the rise as shown in FIG. 2B. Until a DC voltage is obtained and the fall reaches DC 340 V, a high level “1” is obtained at the output terminal RY of the one-chip microcontroller 30 as shown in FIG. 2D.
[0043]
The output signal obtained at the output terminal RY of this one-chip microcontroller 30 is supplied to the base of an npn transistor 31 that controls the relay 7, the emitter of this transistor 31 is grounded, and the collector of this transistor 31 constitutes the relay 7. When the output terminal RY of the one-chip microcontroller 30 is at a high level “1”, a current is supplied to the electromagnetic device 7b of the relay 7 to turn on the connection switch 7a.
[0044]
For example, a DC voltage of DC 390 V obtained at one and the other output terminals 6 c and 6 d of the PFC circuit 6 is supplied to the main converter circuit 26, and the DC voltage obtained at the output terminals 26 a and 26 b of the main converter circuit 26 is supplied to the main device. Supply as (set) power. The main converter circuit 26 is, for example, an insulating flyback converter circuit, and converts the DC side voltage of 390V to a DC voltage used by the secondary side main unit (set) or the like, for example, DC12V.
[0045]
Further, the DC voltage obtained at the output terminals 6c and 6d of the PFC circuit 6 is supplied to the auxiliary power supply circuit 27 that supplies power to the primary side control circuit and the secondary side control circuit of the main converter circuit 26. To do.
[0046]
The auxiliary power circuit 27 is composed of a switching type constant voltage circuit controlled by a pulse width modulation control integrated circuit (PWM control IC) 27a. One output terminal 6c of the PFC circuit 6 is connected to a starting resistor 27b. Is connected to the power supply terminal Vcc to which the operating voltage of the PWM control IC 27a is supplied, and this one output terminal 6c is connected to the field effect transistor 27c constituting the switching element via the primary winding 28a of the transformer 28. The PWM control IC 27a is connected to the drain, the source of the field effect transistor 27c is grounded, and the gate of the field effect transistor 27c is pulse-modulated in accordance with the output voltage of the auxiliary power circuit 27. To the switching signal output terminal OUT.
[0047]
An AC signal obtained from the secondary winding 28b of the transformer 28 is supplied to the rectifier circuit 29, and a DC voltage obtained from the output terminals 29a and 29b of the rectifier circuit 29 is used as a power source for a control circuit such as a main device (set). As used.
[0048]
One end of the tertiary winding 28c of the transformer 28 is connected to the power supply terminal Vcc for supplying the operating voltage of the control IC 6h via the rectifying diode 27d, and the output voltage of the auxiliary power circuit 27 of the PWM control IC 27a is used. Connected to an output voltage input terminal VS for supplying a corresponding voltage. The other end of the tertiary winding 28c is grounded. A connection point between the diode 27d and the output voltage input terminal VS of the PWM control IC 27a is grounded through a smoothing capacitor 27e.
[0049]
The connection point between the diode 27d and the capacitor 27e is connected to the power supply terminal Vcc of the PWM control IC 27a through the backflow prevention diode 27f, and the connection point between the diode 27f and the power supply terminal Vcc of the PWM control IC 27a is used for smoothing. Is grounded through a capacitor 27g. Further, the connection point of the diode 27d and the capacitor 27e is connected to one end of the electromagnetic device 7b of the relay 7.
[0050]
In this example, a non-volatile memory such as an EEPROM (Electrical Erasable Programmable ROM) 32 is provided in association with the one-chip microcontroller 30, and the EEPROM 32 is preliminarily configured in the following manner when the power supply device is manufactured. The detection reference voltage value is stored.
[0051]
When the various detection reference voltage values are stored, the one-chip microcontroller 30 is set in the test mode, so that the test mode is set in the determination of step S1 in the flowchart shown in FIG. In step S2 of this test mode, a reference AC 70 V is supplied to the power plug 1 of the power supply device, and the AC voltage detection terminal V of the one-chip microcontroller 30 at this time is supplied. _AC Then, the detected reference AC voltage value is stored in the work RAM of the one-chip microcontroller 30 via the AD converter.
[0052]
In the next step S3, an abnormal AC 330V, for example, is supplied to the power plug 1 of the power supply device, and the AC voltage detection terminal V of the one-chip microcontroller 30 at this time is supplied. _AC The detected abnormal AC voltage value is stored in the work RAM of the one-chip microcontroller 30 via the AD converter.
[0053]
In this case, the detection reference AC voltage value and the detected abnormal AC voltage value are values including variations in the resistance values of the resistors 11, 12, 13, and 14, respectively.
[0054]
Next, in step S4, a first reference output voltage, for example, DC340V is supplied between one and the other output terminals 6c and 6d of the PFC circuit 6, and the output voltage detection terminal V of the one-chip microcontroller 30 at this time is supplied. _P The detected first reference output voltage value is stored in the work RAM of the one-chip microcontroller 30 via the AD converter.
[0055]
Next, in step S5, a second reference output voltage, for example, DC370V, is supplied between one and the other output terminals 6c and 6d of the PFC circuit 6, and the output voltage detection terminal V of the one-chip microcontroller 30 at this time is supplied. _P The detected second reference output voltage value is stored in the work RAM of the one-chip microcontroller 30 via the AD converter.
[0056]
Next, in step S6, an overvoltage (a voltage assuming an abnormal voltage of the PFC circuit 6) between one and the other output terminals 6c and 6d of the PFC circuit 6, for example, 430V when the withstand voltage of the smoothing capacitor 6i is 450V. At this time, the output voltage detection terminal V of the one-chip microcontroller 30 is supplied. _P The detected overvoltage value obtained in the above step is stored in the work RAM of the one-chip microcontroller 30 via the AD converter.
[0057]
In this case, the detected first reference output voltage value, the detected second reference output voltage value, and the detected overvoltage value are values including variations in resistance values of the resistors 18, 19, 20, and 21, respectively.
[0058]
In step S7, the detected reference AC voltage value, the detected abnormal AC voltage value, the detected first reference output voltage value, the detected second reference output voltage value, and the detected overvoltage value stored in the work RAM of the one-chip microcontroller 30. Is written and stored in a predetermined address of the EEPROM 32, and the process ends.
[0059]
In this case, the detection reference AC voltage value, the detection abnormal AC voltage value, the detection first reference output voltage value, the detection second reference output voltage value, and the detection overvoltage value are written to the EEPROM 32 every time they are detected. You may do it.
[0060]
Next, the actual use of the power supply device according to this example will be described with reference to the flowchart of FIG. 3 and FIG. Since the one-chip microcontroller 30 is not in the test mode at this time, it is determined in step S1 that it is not in the test mode, and the detection reference AC voltage value, the detection abnormal AC value, the detection first reference output voltage value, and the detection stored in the EEPROM 32 The second reference output voltage value and the detected overvoltage value are read out to the work RAM of the one-chip microcontroller 30 (step S8).
[0061]
Here, FIG. 4 shows modes of the output terminal PF and the output terminal RY of the one-chip microcontroller 30 which are shown in the flowchart of FIG.
[0062]
When commercial power of AC100V is supplied to the power plug 1 as shown in FIG. 2A, the mode is initially set to mode 0 (step S9). At this time, both the output terminals PF and RY are at the low level “0”.
[0063]
Next, AC voltage detection terminal V _AC It is determined whether or not the voltage supplied to is greater than or equal to the detection reference AC voltage value (step S10). This AC voltage detection terminal V _AC When the voltage supplied to the input terminal 4a and 4b of the full-wave rectifier circuit 4 is equal to or higher than, for example, AC 70V, the output terminal PF is at the high level “ At this time, the control IC 6h of the PFC circuit 6 is activated, and the output voltage of the output terminals 6c and 6d of the PFC circuit 6 rises as shown in FIG. 2B (the PWM control IC 27a of the auxiliary power circuit 27 is AC This is started before the voltage reaches 70 V, and the auxiliary power circuit 27 is also in an operating state.) At this time, the inrush current preventing resistor 5 is inserted until the relay 7 operates, and the inrush current is blocked.
[0064]
Next, the process proceeds to step S11, where it is determined whether or not the mode 2 is selected. _P It is determined whether or not the voltage obtained in step S12 is equal to or higher than the detected second reference output voltage value (step S12). When the voltage is equal to or lower than the detected second reference output voltage value, mode 1 is set (step S13). When the output voltage of the output terminals 6c and 6d of the circuit 6 rises as shown in FIG. 2B and the output voltage of the output terminals 6c and 6d becomes, for example, DC370V or more, the mode 2 is set (step S14), and the output terminal RY also becomes high level “1”, the transistor 31 is turned on, a current flows through the electromagnetic device 7b of the relay 7, the connection switch 7a is turned on, and the current is supplied to the PFC circuit 6 via this connection switch 7a.
[0065]
In this case, AC voltage detection terminal V _AC It is determined whether or not the detection voltage supplied to the detection abnormal AC voltage value or more, that is, the AC voltage supplied to the power plug 1 is, for example, AC 330 V or more (step S15) and the output voltage detection terminal V _P It is determined whether or not the detection voltage supplied to the output voltage is equal to or greater than the detected overvoltage value, that is, the output voltage is equal to or higher than the overvoltage, for example, 430 V (step S16). If “Yes” in any of steps S15 and S16, an abnormality process is performed (step S17).
[0066]
When the AC power supply is turned off and the supply of AC 100V commercial power to the power plug 1 is stopped, the AC voltage detection terminal V is detected in step S10. _AC Is determined to be equal to or lower than the detection reference AC voltage value, and the process proceeds to step S18 to determine whether or not the mode is 0.
[0067]
When the supply of AC 100 V commercial power is stopped, the output voltage at the output terminals 6c and 6d of the PFC circuit 6 decreases as shown in FIG. 2B. If it is determined in step S18 that the mode is not 0, the process proceeds to step S19, and the output voltage detection terminal V _P It is determined whether or not the obtained voltage is equal to or lower than the detected first reference voltage value, that is, whether the output voltage at the output terminals 6c and 6d is equal to or lower than DC 340V, for example. If not lower, the mode 3 is set (step S20). In this mode 3, the output terminal PF is at the low level “0” and the control IC 6h of the PFC circuit 6 is inoperative, but the output terminal RY is at the high level “1”, and the connection switch 7a of the relay 7 is Stays on.
[0068]
When the mode is 0 in step S18 and in step S19, the output voltage detection terminal V _P When the obtained voltage is equal to or lower than the detected first reference voltage value, mode 0 is set (step S21). Steps S13, S20 and S21 each move to step S15.
[0069]
According to this example, a reference AC voltage and an abnormal AC voltage are supplied in advance to the power plug 1 at the time of manufacture, for example. _AC The detected reference AC voltage value and the detected abnormal AC voltage value are stored in the EEPROM 32, and the first reference output voltage, the second reference output voltage and the overvoltage are supplied to the output terminals 6c and 6d of the power factor correction circuit 6. The output voltage detection point of the power factor correction circuit 6, that is, the output voltage detection terminal V _P The detected first reference output voltage value, the detected second reference output voltage value, and the detected overvoltage value are stored in the EEPROM 32, and the detected reference AC voltage value and the detected abnormal AC voltage stored in the EEPROM 32 during actual use. Value, detection first reference output voltage value, detection second reference output voltage value and detection overvoltage value are used to detect the input AC voltage and the output voltage of the power factor correction circuit. The reference AC voltage value, detection abnormal AC voltage value, detection first reference output voltage value, detection second reference output voltage value, and detection overvoltage value are resistors 11, 12, 13, 14, 18, 19, 20, 21. Thus, the input AC voltage and the output voltage of the output terminal of the power factor correction circuit can be accurately detected without any adjustment, and no malfunction occurs.
[0070]
In addition, according to this example, the input AC voltage and the output voltage of the power factor correction circuit are digitally processed using the detected reference AC voltage value stored in the EEPROM 32 during actual use, the detected first and second reference output voltage values, and the like. Therefore, the relay 7 and the control IC 6h are controlled, so that chattering does not occur and the operation state and the non-operation state are not repeated in a short period of time, so that the operation can be performed satisfactorily.
[0071]
Of course, the present invention is not limited to the above-described examples, and other kinds of configurations can be adopted without departing from the gist of the present invention.
[0072]
【The invention's effect】
According to the present invention, a reference AC voltage is supplied in advance to the commercial AC voltage input terminal, and the detected reference AC voltage value obtained at this AC voltage detection point is stored in the nonvolatile memory and also output to the power factor correction circuit. A reference output voltage is supplied, and the detected reference output voltage value obtained at the output voltage detection point of the power factor correction circuit is stored in a nonvolatile memory, and the detected reference AC voltage stored in the nonvolatile memory during actual use Value and detection reference output voltage value are used to detect the input AC voltage and the output voltage of the power factor correction circuit. The detection reference AC voltage value and the detection reference output voltage value are elements such as resistors. Thus, the input AC voltage and the output voltage of the output terminal of the power factor correction circuit can be accurately detected without any adjustment, and no malfunction occurs.
[0073]
Further, according to the present invention, the input AC voltage and the output voltage of the power factor correction circuit are detected by digital processing using the detection reference AC voltage value and the detection reference output voltage value stored in the nonvolatile memory during actual use, and relayed. In addition, since the control IC is controlled, chattering is not caused, and the operation state and the non-operation state are not repeated in a short period of time, so that the operation can be performed satisfactorily.
[Brief description of the drawings]
FIG. 1 is a configuration diagram showing an example of an embodiment of a power supply device according to the present invention.
FIG. 2 is a timing chart for explaining the present invention.
FIG. 3 is a flowchart for explaining the present invention.
FIG. 4 is a diagram for explaining the present invention.
FIG. 5 is a configuration diagram illustrating an example of a conventional power supply device.
FIG. 6 is a timing chart for explaining FIG. 5;
[Explanation of symbols]
DESCRIPTION OF SYMBOLS 1 ... Power plug, 4 ... Full wave rectification circuit, 5, 11, 12, 13, 14, 18, 19, 20, 21 ... Resistor, 6 ... PFC circuit, 7 ... Relay, 26 ... Main converter circuit, 27 ... auxiliary power supply circuit, 28 ... transformer, 29 ... rectifier circuit, 30 ... 1 chip microcontroller, 31 ... transistor, 32 ... EEPROM

Claims (2)

The commercial AC voltage inputted to a commercial AC voltage input terminal, a power supply device that converts to a Jo Tokoro DC voltage using a power factor correction circuit,
A resistor for preventing inrush current provided in the previous stage of the power factor correction circuit;
A relay connected in parallel with the resistor;
When a predetermined reference AC voltage is supplied to the commercial AC voltage input terminal, a detected reference AC voltage value detected at a commercial AC voltage detection point, a predetermined first reference output voltage, and the first reference output voltage When each larger second reference output voltage is supplied to the output terminal of the power factor correction circuit, the first detection reference output voltage value detected at the output voltage detection point of the power factor correction circuit and the second A non-volatile memory in which a detection reference output voltage value is stored in advance ;
The commercial AC voltage and the output voltage of the power factor correction circuit are detected, and based on the detected commercial AC voltage, the output voltage of the power factor correction circuit, and each value stored in the nonvolatile memory, the power A rate correction circuit and a microcontroller for controlling the relay,
The microcontroller is
The power factor correction circuit is operated when the detected commercial AC voltage becomes equal to or higher than the detection reference AC voltage value, and the detected output voltage of the power factor correction circuit is equal to or higher than the second detection reference output voltage value. Turns on the relay,
Even when the supply of the commercial AC voltage is stopped and the detected commercial AC voltage becomes smaller than the detection reference AC voltage value, the detected output voltage of the power factor correction circuit is the first detection reference output voltage. A power supply that keeps the relay on for as long as the value is greater . Further, when the abnormal AC voltage is supplied to the commercial AC voltage input terminal, the nonvolatile memory has a detected abnormal AC voltage value detected at a commercial AC voltage detection point and an overvoltage that is output from the power factor correction circuit. A detection overvoltage value detected at an output voltage detection point of the power factor correction circuit when supplied to the terminal, is stored in advance;
The microcontroller performs an abnormality process when the detected commercial AC voltage or the output voltage of the power factor correction circuit becomes equal to or higher than the detected abnormal AC voltage value or the detected overvoltage value.
The power supply device according to claim 1 .

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