JP2011250523A - Power supply device and electronic apparatus having the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress flowing of a rush current by suddenly applying a voltage of a specified value to a circuit with a configuration cheaper than a conventional one.SOLUTION: When a switch connecting a DC voltage generation circuit with a stabilization circuit and a first circuit that operates at a DC voltage of a specified value opens and then closes again, a first DC voltage value generated by the DC voltage generation circuit is lowered to a second DC voltage value, which is lower than the specified value, and then is increased to the specified value again. This can suppress flowing of a rush current by suddenly applying a voltage of the specified value to the first circuit and the stabilization circuit.

Description

  The present invention relates to an electronic device including a power source that generates a DC voltage based on an AC voltage supplied from a commercial power source.

  An electronic device such as an image forming apparatus is provided with a door for an operator to access the inside. The door is provided with an interlock switch that operates in conjunction with opening and closing of the door. According to Patent Document 1, it is proposed to switch the operation of a switching power supply for a power system that supplies power to a power load and a switching power supply for a control system that supplies power to a control circuit according to the open / close state of the interlock switch. ing. Specifically, when the interlock switch detects that the door is open, the power system switching power supply stops oscillation. When the interlock switch detects that the door is closed, the power switching power supply resumes oscillation.

  In general, a capacitor is provided in front of a load circuit that operates with power supplied from a power supply device in order to stabilize the supply voltage. However, when the interlock switch is opened and closed, a rush current flows into the capacitor and the like, which may destroy the capacitor. According to Patent Document 2, it is proposed to reduce an inrush current by providing a semiconductor switch in series with an interlock switch.

JP 2001-142362 A Japanese Patent Laid-Open No. 05-111149

  However, if a semiconductor switch is provided in series with the interlock switch as in Patent Document 2, the cost increases. When the semiconductor switch is turned on, the semiconductor switch consumes power. That is, since a semiconductor switch having a large current capacity is required, the cost is further increased.

  Therefore, an object of the present invention is to solve at least one of such problems and other problems. For example, it aims at providing the structure which reduces the inrush current to stabilization circuits, such as a capacitor | condenser, cheaper than before. Other issues can be understood throughout the specification.

  An electronic apparatus according to the present invention includes a DC voltage generating circuit that converts an AC voltage to generate a variable first DC voltage within a predetermined variable range, and a first circuit that operates by being supplied with the first DC voltage. And a switch for switching between supply and cutoff of the first DC voltage from the DC voltage generation circuit to the first circuit. Furthermore, the electronic device includes a detection circuit that detects opening and closing of the switch, a stabilization circuit that is provided in parallel with the first circuit and stabilizes the first DC voltage supplied via the switch, and a predetermined variable range. And a conversion circuit that converts the variable first DC voltage to generate a constant second DC voltage lower than the first DC voltage. Further, when the electronic circuit detects that the second circuit that is supplied with the second DC voltage and operates and the detection circuit detects that the switch is in the open state, the value of the first DC voltage is the second DC voltage. The DC voltage generator circuit is controlled so that it drops to the voltage value, and when the detection circuit detects that the switch is closed, the DC voltage generator circuit is set so that the first DC voltage value becomes the specified value. And a control circuit for controlling.

  According to the present invention, when the switch connecting the DC voltage generating circuit and the first circuit is opened and closed, the value of the first DC voltage drops to the value of the second DC voltage and then again reaches the specified value. I tried to raise it. Therefore, it is possible to suppress an inrush current from flowing due to sudden application of a specified voltage to the first circuit or the stabilization circuit with a configuration that is less expensive than the conventional one.

It is a figure explaining the power supply system of the electronic device which concerns on Embodiment 1. FIG. 1 is a circuit diagram showing a configuration of a switching power supply according to Embodiment 1. FIG. 3 is a flowchart illustrating main processing according to the first embodiment. 3 is a flowchart illustrating interrupt processing according to the first embodiment. 6 is a diagram illustrating an example of an operation according to Embodiment 1. FIG. 6 is a diagram illustrating an example of an operation according to Embodiment 1. FIG. It is a figure explaining the power supply system of the electronic device which concerns on Embodiment 2. FIG. 10 is a flowchart illustrating main processing according to the second embodiment.

[Embodiment 1]
FIG. 1 is a schematic circuit diagram showing a control system and a drive system of an electronic device 100 to which the features of the present invention are applied. The switching power supply 101 is a DC voltage generation circuit that converts an AC voltage supplied from a commercial power supply and generates a variable first DC voltage within a predetermined variable range. The outlet 102 functions as an input unit of the switching power source 101 and is a terminal connected to a commercial power source. A power output 103 is an output of the switching power supply 101. The power output 103 is variable within a predetermined variable range (for example, 3.3V to 24V). The power output 103 is connected to one end of the interlock switch 104. The interlock switch 104 is a type of switch that switches between supply and cutoff of the first DC voltage from the DC voltage generation circuit to the first circuit. In particular, the interlock switch 104 is a mechanical switch that opens and closes in response to opening and closing of a door for an operator to access the inside of the electronic device. The 24V system power line 105 is connected to the other end of the interlock switch 104 and couples the interlock switch 104 and the 24V system circuit 106. The 24V system circuit 106 is an example of a first circuit to which a first DC voltage is supplied. When an image forming apparatus such as a laser printer is employed as the electronic apparatus 100, the 24V system circuit 106 includes a motor, a solenoid, a high voltage power supply circuit, and the like. The smoothing capacitor 107 is an example of a stabilization circuit that is provided in parallel with the first circuit, is provided in series with the switch, and stabilizes the first DC voltage supplied via the switch. Here, the smoothing capacitor 107 is a kind of capacitive load and functions to stably supply the first DC voltage of 24V to the 24V system circuit 106.

The DC / DC converter 108 is an example of a conversion circuit that converts a variable first DC voltage within a predetermined variable range to generate a second DC voltage that is lower than the first DC voltage and constant. Here, it is assumed that the DC / DC converter 108 receives the power output 103 and outputs 3.3V. The input voltage is variable from 3.3V to 24V, but the output voltage is fixed to a constant value (eg, 3.3V). The 3.3V system power supply line 109 is a line for supplying the output of the DC / DC converter 108 to the 3.3V system circuit 111 and the like. The CPU 110 is a control circuit that comprehensively controls each unit of the electronic device. The 3.3V system circuit 111 is an example of a second circuit that operates by being supplied with a second DC voltage. The voltage dividing resistors 112 and 113 are resistors for monitoring the voltage of the 24V power supply line 105 at a low voltage. The voltage dividing resistors 112 and 113 also function as a detection circuit that detects opening and closing of the switch together with the CPU 110. The input port 114 is a port for the CPU 110 to detect a voltage obtained by dividing the voltage of the 24V system power line 105 by the voltage dividing resistors 112 and 113. The input port 114 includes an A / D conversion circuit. In general, the allowable range of the input voltage of the input port 114 normally has the power supply voltage of the CPU 110 as an upper limit. Therefore, the voltage dividing ratio of the voltage dividing resistors 112 and 113 is set to a value such that the voltage of the 24V system power supply line 105 is 3.3V or less. For example, the partial pressure ratio can be determined as follows.
Resistance value of voltage dividing resistor 112: Resistance value of voltage dividing resistor 113 = 7: 1
Thereby, even when the voltage of the 24V system power line 105 is 24V + 5% of 25.2V, the voltage applied to the input port 114 is 3.15V. The power control line 115 is a signal line connected to the output port of the CPU 110. The CPU 110 sets, for example, whether the power output 103 of the switching power supply 101 is set to 24V or 3.3V by switching the voltage applied to the power supply control line 115 to High or Low.

  As is well known, a laser printer has an image processing device, a laser light emitting device, a laser scanner motor, a fixing device, etc. (not shown). In a normal printing operation, when the output voltage of the switching power supply 101 is 24V, the motor, solenoid and high voltage power supply circuit of the laser printer are driven. When the output voltage of the switching power supply 101 is 3.3 V, these are not driven, and only the CPU 110 connected to the DC / DC converter 108 is in a driving state. That is, when the output voltage is 3.3 V, the switching power supply 101 is in an energy saving mode (hereinafter abbreviated as an energy saving mode), consumes less power, and is in a highly efficient operation state.

  As described above, the interlock switch 104 is opened (open / off) when the door provided on the exterior cover is opened to mount a toner cartridge (not shown) on the laser printer, and is closed (closed) when the door is closed. / On). When the door is opened by an operator or the like, the interlock switch 104 cuts off the power supply to the 24V system circuit 106, so that the laser printer is controlled not to operate carelessly.

  Details of the switching power supply 101 will be described with reference to FIG. As can be seen from FIG. 2, the switching power supply 101 employs a self-excited flyback (RCC) system. A filter circuit 201 for filtering an AC voltage is connected to the outlet 102. A diode bridge 202 and a rectifying capacitor 203 for rectifying an AC voltage are coupled to the subsequent stage of the filter circuit 201. In the switching transformer 204, the primary winding Np includes an auxiliary winding Nb and a secondary winding Ns. In FIG. 2, the left side of the switching transformer 204 is the primary side, and the right side is the secondary side. On the primary side, a starting resistor 205 is provided, and fulfills the function of flowing a starting current when the switching power supply 101 is started. The photocoupler 206 includes a phototransistor 206-a and an LED 206-b. The switching element 207 is an FET (field effect transistor) or the like, and one of the three terminals is coupled to one end of the primary winding Np. The other one of the three terminals is connected to the diode bridge 202 and the rectifying capacitor 203. The primary circuit is further provided with resistors 208, 209, 211, 213, 216, 217, and 251; transistors 210 and 250; capacitors 212 and 218; and a second photocoupler 214 at the positions shown in FIG. ing. The second photocoupler 214 includes a phototransistor 214-a and an LED 214-b. Diodes 215 and 219 are provided at positions shown in FIG. 2 as regulating elements that regulate the flow of current.

  On the secondary side, a secondary rectifier diode 220, an electrolytic capacitor 221, resistors 222, 224, 225, 234, 235, 236, 239, 241, 242, and a shunt regulator 223 are provided at the positions shown in FIG. . Further, on the secondary side, a transistor 240, a comparator 233, a Zener diode 238 for generating a reference voltage, and a diode 230 are provided. The resistors 224, 225, and shunt regulator 223 are set to have resistance values and the like so that the LED 214-b operates when the power output 103 is 24V. The resistors 235, 239, and 236 and the Zener diode 238 have their resistance values set so that the output of the comparator 233 changes when the power output 103 drops from 24V to 3.3V.

  The operation of the switching power supply 101 will be described. In particular, the operation when the power is turned on is as follows. When an AC voltage is applied from the outlet 102 to the diode bridge 202 via the filter circuit 201, the two-wave rectification is performed by the diode bridge 202. Further, peak charging is performed by the rectifying capacitor 203. As a result, a DC voltage is generated across the rectifier capacitor 203. When the switching power supply 101 is activated, a current flows from the activation resistor 205 to the transistor 250. As a result, the voltage applied to the gate of the switching element 207 is increased, the switching element 207 is turned on, and a current begins to flow through the primary winding Np of the switching transformer 204. At this point, no voltage is generated on the secondary side. Therefore, the LED 206-b is not turned on, and thus the phototransistor 206-a is not turned on. As a result, a bias current flows through the resistor 251 and the transistor 250 is turned on. A voltage is generated in the auxiliary winding Nb by the current flowing through the primary winding Np. This voltage is applied to the gate terminal of the switching element 207 via a capacitor 212 and a resistor 211 connected in series with the auxiliary winding Nb. Therefore, the gate voltage increases. In parallel with this, a current flows through the resistor 217 by the voltage generated in the auxiliary winding Nb, and the capacitor 218 is charged. After a certain time from the start of charging, the voltage across the capacitor 218 reaches a voltage for turning on the transistor 210, and as a result, the switching element 207 is turned off. When the switching element 207 is turned OFF, a current flows through the secondary winding Ns in a direction (forward direction) in which the secondary rectifier diode 220 is conducted. The electrolytic capacitor 221 is charged by this current. When the energy stored in the switching transformer 204 is released, a ringing voltage is generated in the auxiliary winding Nb. The switching element 207 is turned on again by this ringing voltage. Thus, oscillation occurs and the switching power supply 101 is activated.

  The operation after the switching power supply 101 is started is as follows. First, when an instruction to start a printing operation is given, the CPU 110 sets the power control line 115 to High and the power output 103 to 24V. When the power supply control line 115 becomes high, the transistor 240 is turned on. As a result, the voltage across the resistor 239 decreases, and the value of the voltage applied to the negative terminal of the comparator 233 is almost at the GND level. The Zener voltage of the Zener diode 238 is applied to the plus terminal of the comparator 233. Therefore, since the comparator 233 outputs High, the LED 206-b is not lit. The diode 230 is connected in a direction in which no current flows even if the comparator 233 outputs High. Therefore, the fact that the comparator 233 outputs High does not affect the operation of the LED 214-b. In this situation, when the power output 103 becomes 24V or more, the LED 214-b is lit by the operation of the shunt regulator 223. As a result, the phototransistor 214-a is turned on. By such an operation, the time for which the switching element 207 is turned on is adjusted, so that the power output 103 is stabilized at 24V.

  Incidentally, an electronic device such as a laser printer has an energy saving mode. When shifting to the energy saving mode, the CPU 110 sets the power control line 115 to Low and sets the power output 103 to 3.3V. As a result, the supply of power to the 24V system circuit is cut off, and power is supplied to the CPU 110 and the 3.3V system circuit 111. When the power control line 115 shifts to Low, the transistor 240 is turned off. As a result, when the power output 103 decreases to 3.3 V, the output of the comparator 233 is switched. When the power output 103 is higher than 3.3V, the comparator 233 outputs Low, turns on the LED 206-b, and turns on the LED 214-b through the diode 230. When the auxiliary winding Nb tries to turn on the switching element 207, the transistor 210 is turned on by turning on the LED 214-b. As a result, the switching element 207 shifts to OFF. In this way, the RCC operation by the auxiliary winding Nb is stopped. On the other hand, since the LED 206-b is lit, the phototransistor 206-a is turned on. As a result, since the transistor 250 shifts to OFF, no current flows through the starting resistor 205. When the power output 103 falls below 3.3V, the output of the comparator 233 is switched to High. Accordingly, the LED 206-b is turned off, and the switching power supply is started by the starting resistor 205. As described above, the switching power supply 101 can be repeatedly started and stopped at a very low frequency. Therefore, since the repetition frequency of starting and stopping becomes low, loss due to switching is reduced, and the switching power supply 101 is operated with high efficiency.

  Here, a characteristic with a maximum output of 150 W will be described as an example of the characteristic of the RCC switching power supply. The RCC switching power supply without the energy saving mode described above oscillates at about 150 KHz in a no-load state at 24 V output, power consumption is less than 5 W, and power conversion efficiency is only about 20%. On the other hand, according to the switching power supply 101 having the energy saving mode of the present invention, at 3.3 V output, it oscillates at about 500 Hz in a no-load state, power consumption is 1 W or less, and power conversion efficiency is about 60%. Therefore, the switching power supply 101 of the present invention can realize a power supply device with high efficiency and low power consumption.

  A program executed by the CPU 110 will be described with reference to FIGS. 3 to 4. FIG. 3 shows a main process flowchart of the entire apparatus, and FIG. 4 shows an interrupt process flowchart. When the outlet 102 is connected to a commercial power source in S301, the switching power source 101 is activated. The DC / DC converter 108 supplied with the DC voltage from the switching power supply 101 further supplies power to the CPU 110. The CPU 110 loads a program from a storage device such as a ROM into the RAM and starts it. Thereafter, the CPU 110 implements various functions according to the program.

  In S302, the CPU 110 activates a timer interrupt to permit the timer interrupt. This interruption is confirmation processing of the interlock switch shown in FIG. The timer interrupt process is started by an interrupt process at regular intervals set during the main process of the CPU 110 by operating a timer circuit (not shown), and starts from S401. In S402, the CPU 110 takes in and measures the voltage applied to the input port 114 by A / D conversion. The measured voltage is obtained by dividing the voltage of the 24V power supply line 105 by the voltage dividing resistors 112 and 113. Therefore, the CPU 110 calculates the actual voltage of the 24V power supply line 105 from the voltage dividing ratios of the voltage dividing resistors 112 and 113 and the measured value. In S403, the CPU 110 branches the process according to the calculated voltage of the 24V system power line 105. The voltage classification of the 24V system power line 105 is 3.3V and 24V, but the accuracy ranges are 3.1V or more and less than 3.5V, and 23V or more and less than 25V. Therefore, if the calculated value is less than 3.1 V, the CPU 110 determines that the interlock switch 104 is open (that is, the door is open), and proceeds to S404. In S404, the CPU 110 sets the power control line 115 to Low. As a result, the output voltage of the switching power supply 101 starts to drop, and finally the power supply output 103 is set to 3.3V. In S405, the CPU 110 sets the operation mode to “door open mode”. If the voltage of the 24V system power line 105 is not less than 3.1V and less than 3.5V, the CPU 110 determines that the voltage is stable at 3.3V and proceeds to S406. In S406, CPU 110 sets the operation mode to “3.3 V mode”. If the voltage of the 24V system power line 105 is not less than 3.5V and less than 23V, the CPU 110 determines that the voltage is being changed, and proceeds to S407. In S407, the CPU 110 sets the operation mode to “voltage changing mode”. If the voltage of the 24V system power line 105 is 23V or more, the CPU 110 determines that the voltage is stable at 24V, and proceeds to S408. In S408, the CPU 110 sets the operation mode to “24V mode”. In accordance with this interrupt program, the CPU 110 delivers “four operation modes” as “interlock switch state” to the main process flowchart of FIG. 3, and ends the interrupt process in S409.

  Returning to the description of FIG. In S303, the CPU 110 sets the power output 103 to 3.3V by setting the power control line 115 to High. In S <b> 304, the CPU 110 waits until the state of the interlock switch 104 becomes “3.3 V mode”. If it can be confirmed that 3.3V is output to the 24V system power line 105 because the door is closed, the process proceeds to S305.

  In S305, the CPU 110 sets the power output 103 to 24V by switching the power control line 115 to High. In S306, the CPU 110 branches the process according to the state of the interlock switch 104. If the power output 103 does not rise to 24V (3.3V mode or voltage changing mode), the CPU 110 waits until the power output 103 rises to 24V. When the power output 103 rises to 24V, the process proceeds to S308. On the other hand, if it is a door open mode, it will progress to S307. In S307, the CPU 110 switches the power control line 115 to High, sets the power output 103 to 3.3V, and returns to S304. As described above, when the detection circuit detects that the switch is opened, the CPU 110 controls the DC voltage generation circuit so that the value of the first DC voltage is reduced to the value of the second DC voltage. Functions as a control circuit. If the CPU 110 determines that the power output 103 has not decreased to 3.3V, the power output 103 further decreases the power output 103. On the other hand, when it is confirmed in S304 that the door is closed and the power output 103 is lowered to 3.3V, the CPU 110 raises the power output 103 to 24V which is a specified value again. As described above, when the detection circuit detects that the switch is closed, the CPU 110 also functions as a control circuit that controls the DC voltage generation circuit so that the value of the first DC voltage becomes a specified value. Further, when the detection circuit detects that the switch is closed, the CPU 110 functions as a determination unit that determines whether or not the value of the first DC voltage has decreased to the value of the second DC voltage. As can be seen from S306, when the CPU 110 shifts to the door open mode while the voltage is rising from 3.3V to the specified value of 24V (voltage changing mode), the CPU 110 powers again to 3.3V. The output 103 is reduced. That is, when the detection circuit detects again that the switch has been opened before the value of the first DC voltage reaches the specified value after the start of the increase of the first DC voltage, It functions as a control circuit that lowers the DC voltage.

  In step S308, the CPU 110 executes printer initial setting and initial operation. The printer initial setting and the initial operation include, for example, a setting process necessary for executing printing, a remaining paper check process, and the like. For example, the residual paper check process is a process in which the CPU 110 uses a sheet sensor or the like to check whether recording paper remains in the printer. If there is no remaining paper, the CPU 110 drives a drive motor, a laser scanner, etc., and performs an operation check of each unit. As a result, the toner cartridge shifts to a printable state. Note that the CPU 110 always checks the state of the interlock switch during the printer initial setting and the initial operation. If the CPU 110 detects a voltage drop in the 24V system power line 105 other than the “24V mode”, that is, the process proceeds to S307. In S307, the CPU 110 switches the power control line 115 to High, sets the power output 103 to 3.3V, and returns to S304. When S308 ends, the process proceeds to S309.

  In S309, the CPU 110 switches the power control line 115 to Low and sets the power output 103 to 3.3V. In S310, the CPU 110 branches the process according to the state of the interlock switch 104. If the power output 103 is not lowered to 3.3V (24V mode or voltage changing mode), the CPU 110 waits until the power output 103 is lowered to 3.3V. When the power output 103 drops to 3.3V (when the mode is changed to 3.3V mode), the process proceeds to S311. If it is the door open mode, the process proceeds to S307.

  In step S311, the CPU 110 confirms whether printing is started. This is a process for determining whether the CPU 110 has received a print start command from a personal computer or the like to which a laser printer (not shown) is connected. CPU 110 waits until a print start command is received. When the print start command is received, the process proceeds to S312.

  In S312, the CPU 110 sets the power output 103 to 24 V by switching the power control line 115 to High. The process proceeds to S313. In step S <b> 313, the CPU 110 branches the process according to the state of the interlock switch 104. If the power output 103 does not rise to 24V (3.3V mode or voltage changing mode), the CPU 110 waits until the power output 103 rises to 24V. When the power output 103 rises to 24V (that is, when shifting to the 24V mode), the process proceeds to S314. On the other hand, if it is a door open mode, it will progress to S307. In step S314, the CPU 110 executes a print operation. The above-described main process flowchart is repeatedly executed until the outlet 102 is connected to the commercial power supply and then disconnected.

  The switching power supply 101 realizes binary switching between the highest voltage (example: 24 V) and the lowest voltage (example: 3.3 V) by setting the voltage from the CPU 110 by the power supply control line 115. As described above, if the DC / DC converter has substantially the same minimum input voltage (eg, 3.3 V) as the output of the switching power supply 101, power loss by the DC / DC converter 108 hardly occurs. Therefore, when the output voltage of the switching power supply 101 is lowered, the power loss can be minimized by setting the lowest value in the output voltage range. The lowest value (e.g., 3.3 V) in the variable range of the power output 103, which is the first DC voltage, matches the value of the second DC voltage specified to be output by the DC / DC converter 108. Is set to

  FIG. 5 is a diagram showing an example of the operation of the laser printer. When the initial operation is completed, the laser printer shifts to a stop state (print standby state). At time t1, the laser printer starts printing according to a print start command. That is, the laser printer operates in the 3.3V mode until time t1, and operates in the voltage changing mode from time t1 to t2. At time t2, the laser printer shifts to the 24V mode. When the door is opened at time t3 during the printing operation, the laser printer operates in the voltage changing mode, so that the power output 103 decreases toward 3.3V. Transition to the door open mode at time t4. At time t5, the door is closed by the operator, and the CPU 110 shifts to the 3.3V mode. Initially, 3.3V is output to the 24V system power line 105. At time t6, the CPU 110 shifts to the voltage changing mode, so that the voltage of the power output 103 starts to rise, and the voltage of the 24V system power line 105 also rises. At time t7, the voltage of the 24V system power line 105 reaches 24, and the CPU 110 shifts to the 24V mode.

  FIG. 6 is also a diagram illustrating an example of the operation of the laser printer. 6 differs from FIG. 5 in that the door is closed immediately after being opened during the printing operation. That is, the interlock switch 104 is closed before the voltage of the power output 103 decreases to 3.3V. In this embodiment, in order to alleviate the inrush current described above, the CPU 110 confirms that the 24V system power line 105 has dropped to 3.3V when the door state is opened even for a moment, and then the CPU 110 supplies the switching power supply 101 with 24V. Start climbing to. Thus, when the door is closed (that is, when the interlock switch 104 is closed), the 24V system power supply line 105 is controlled to rise from 3.3V to 24V. Therefore, 24V is not suddenly applied to the smoothing capacitor 107 connected to the 24V system power line 105. Therefore, the inrush current does not easily flow through the 24V system power line 105.

  Conventionally, it is necessary to design the current capacity of the interlock switch 104 to withstand the inrush current, or to increase the peak current that can be supplied by the switching power supply 101. On the other hand, in this embodiment, since it is not necessary to deal with such a large current, it is possible to reduce the cost of the electronic device 100 by adopting cheaper electronic components.

  In the present embodiment, in order to clarify the operation mode of the switching power supply 101, it has been described that the process waits particularly until the power supply output 103 drops to 3.3V in S304. This is particularly effective in a switching power supply in which the operation becomes unstable by switching the voltage applied to the power supply control line 115 as necessary. However, when the switching power supply 101 adopts a configuration in which the voltage applied to the power supply control line 115 is freely switched, S304 may be omitted, and the process may directly transition from S307 to S305. In this case, the voltage of the power output 103 is switched from a decrease to an increase at the same time when the door state in FIG. 6 is changed from “open” to “closed”. Therefore, the state of the interlock switch 104 is switched to the 24V mode earlier, and the CPU 110 can start the initial operation earlier.

  The present embodiment employs a detection circuit that detects the output voltage of the switching power supply 101 through the 24V power supply line 105. However, a detection circuit that detects the output voltage of the switching power supply 101 through the power supply output 103 may be employed. In other words, the circuit may be changed so that the voltage dividing resistor 112 connected to the 24V system power line 105 is connected to the power output 103. However, the ON / OFF state of the interlock switch 104 cannot be detected as it is. Therefore, an input port for detecting the ON / OFF state of the interlock switch 104 may be added to the CPU 110. The connection point of the added input port may be the same as the connection point of the voltage dividing resistor 112 shown in FIG.

  The remaining part of the electronic device 100 excluding the 24V system circuit 106 and the 3.3V system circuit 111 constitutes a power supply device. Further, the technical idea of the present invention is in the power supply unit, and can be applied to electronic devices other than the image forming apparatus.

[Embodiment 2]
The second embodiment will be described with reference to FIGS. Here, only parts different from the first embodiment will be described in order to simplify the description. FIG. 7 is a circuit diagram showing a control system and a drive system of the electronic apparatus 700. Here, for convenience of explanation, the electronic device 700 is a laser printer. Although the interlock switch 104 is used as a switch in the first embodiment, a semiconductor switch is used here.

  The FET 701 is a switch for switching whether to supply or cut off the DC voltage to the 24V system power line 105 to which the 24V system circuit 106 and the smoothing capacitor 107 are connected. One end of the resistor 702 is connected to the power supply output 103, and the other end is connected to the gate terminal of the FET 701 and one end of the resistor 703. The transistor 704 is a transistor for driving the FET 701 by the CPU 110. The collector terminal of the transistor 704 is connected to the other end of the resistor 703. The emitter terminal of the transistor 704 is grounded. The base terminal of the transistor 704 is connected to the CPU 110 via a resistor 705 and an FET control line 706. The FET control line 706 is a signal line for controlling ON / OFF of the FET 701. The CPU 110 turns on the transistor 704 by switching the voltage level of the FET control line 706 to High. As a result, the FET 701 becomes conductive, and the DC voltage from the switching power supply 101 is supplied to the 24V system circuit 106. In addition, the CPU 110 turns off the transistor 704 by switching the FET control line 706 to Low. As a result, the FET 701 is cut off. As described above, the FET 701 is a semiconductor switch arranged not to supply power to the 24V circuit 106 in order to reduce power consumption during non-printing.

  FIG. 8 is a flowchart showing processing executed by the CPU 110 by starting a program. Note that the same reference numerals are assigned to the steps common to the first embodiment to simplify the description. In S301, the CPU 110 is activated. In S305, the CPU 110 sets the power output 103 to 24V, and in S801, the CPU 110 waits for a certain period of time to elapse. This fixed time is a time required until the output voltage of the switching power supply 101 is reliably stabilized. For example, the waiting time required for the transition from 24V to 3.3V may be different from the waiting time required for the transition from 3.3V to 24V. Therefore, in consideration of this, that is, the fixed time may be set equal to or slightly longer than the longer waiting time. In step S308, the CPU 110 executes initial setting and initial operation of the printer. In S309, the CPU 110 sets the power output 103 to 3.3V. In step S802, the CPU 110 waits for a certain period of time until the voltage becomes stable. In step S <b> 803, the CPU 110 switches the level of the FET control line 706 to Low, thereby causing the FET 701 to transition to the cutoff state. As a result, power is not supplied to the 24V system circuit 106 and the smoothing capacitor 107. In step S310, a print start command is awaited. By repeating this standby loop when printing is not performed, low power consumption can be achieved when printing is not performed. When a print start command arrives, the process exits the standby loop. In step S804, the CPU 110 switches the FET control line 706 to High and causes the FET 701 to transition to a conductive state. As a result, the DC voltage from the switching power supply 101 is supplied to the 24V system circuit 106 and the smoothing capacitor 107. In S312, the CPU 110 sets the power output 103 to 24V. In step S805, the CPU 110 waits for a predetermined time. In step S314, the CPU 110 executes a print operation. When the printing operation is completed, the process returns to S309.

  In particular, the power output 103 is set to 3.3 V by the series of control of S309, S802, S803, S310, S804, S312, and S805, and power consumption can be reduced by waiting for a print start command. By setting the power output 103 to 24V after 3.3V, the voltage applied to the smoothing capacitor 107 gradually increases from 3.3V to 24V. Therefore, inrush current hardly flows through the smoothing capacitor 107. Therefore, the same effects as those of the first embodiment are also obtained in the second embodiment.

Claims (7)

A DC voltage generating circuit for converting the AC voltage to generate a first DC voltage;
A first circuit that operates by being supplied with the first DC voltage;
A switch for switching between supply and cutoff of the first DC voltage from the DC voltage generation circuit to the first circuit;
A detection circuit for detecting opening and closing of the switch;
A stabilization circuit that is provided in parallel with the first circuit and stabilizes the first DC voltage supplied via the switch;
A conversion circuit that converts the first DC voltage to generate a second DC voltage that is lower and constant than the first DC voltage;
A second circuit that operates by being supplied with the second DC voltage;
When the detection circuit detects that the switch is open, the DC voltage generation circuit is controlled so that the value of the first DC voltage is reduced to the value of the second DC voltage, And a control circuit that controls the DC voltage generation circuit so that the value of the first DC voltage becomes a specified value when the detection circuit detects that the switch is closed. Electronics.   When the detection circuit detects that the switch has been closed, the control circuit determines whether the value of the first DC voltage has decreased to the value of the second DC voltage. And when the determination means determines that the value of the first DC voltage has not decreased to the value of the second DC voltage, the first DC voltage is further reduced, 2. The electronic apparatus according to claim 1, wherein when the determination unit determines that the voltage value has decreased to the second DC voltage value, the first DC voltage starts to increase.   The detection circuit again detects that the switch has been opened before the value of the first DC voltage reaches the specified value after the first DC voltage starts to rise. The electronic device according to claim 2, wherein when detected, the first DC voltage is decreased. A door for an operator to access the electronic device;
The electronic device according to any one of claims 1 to 3, wherein the switch is a mechanical switch that opens and closes according to opening and closing of the door.   The electronic device according to claim 1, wherein the switch is a semiconductor switch controlled by the control circuit.   The electronic device according to claim 1, wherein the stabilization circuit is a capacitive load. A DC voltage generating circuit that converts an AC voltage, generates a first DC voltage, and supplies the first DC voltage to an electronic device;
A switch for switching between supply and cutoff of the first DC voltage from the DC voltage generation circuit to the electronic device;
A detection circuit for detecting opening and closing of the switch;
A stabilization circuit provided in parallel with the electronic device and stabilizing the first DC voltage supplied via the switch;
A conversion circuit that converts the first DC voltage to generate a second DC voltage that is lower than the first DC voltage and constant;
When the detection circuit detects that the switch is open, the DC voltage generation circuit is controlled so that the value of the first DC voltage is reduced to the value of the second DC voltage, And a control circuit that controls the DC voltage generation circuit so that the value of the first DC voltage becomes a specified value when the detection circuit detects that the switch is closed. apparatus.

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