JP2017143601A - Power supply device and image forming apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To make a transition from a power saving state to a normal state in a short time.SOLUTION: There is provided a power supply device 100 comprising: a switching power supply part 6 that generates a DC voltage from an AC voltage and outputs the voltage to a load; a relay 2 that switches a connection state between a commercial AC power supply 1 and the switching power supply part 6; a control part 7 that controls the relay 2 to supply a power from the switching power supply part 6 to the load and stops the supply of power; and a switch 13 that instructs the start-up and stop of the switching power supply part 6, where when detecting an instruction to stop the switching power supply part 6 with the switch 13, the control part 7 blocks the connection between the commercial AC power supply 1 and the switching power supply part 6 with the relay 2 after the lapse of time Tdly according to the AC voltage from the commercial AC power supply 1 input to the switching power supply part 6, and stops the supply of power to the load.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a power supply device and an image forming apparatus including the power supply device.

  The image forming apparatus includes a power supply device that generates a DC voltage from an AC voltage input from a commercial AC power supply and supplies electric power to the image forming apparatus. In accordance with the state of the image forming apparatus, for example, the power supply apparatus stops power supply and reduces power consumption in the power supply apparatus in a sleep state that is a power saving state that transitions when image formation is not performed for a predetermined time. . For example, in Patent Document 1, the power supply device includes a power storage circuit, and a relay provided between a switching power supply unit that generates a voltage to be output to a load and a commercial AC power supply is disconnected by power supplied from the power storage circuit. . As a result, a technique for stopping power supply from the commercial AC power supply to the switching power supply unit and reducing power consumption in the power supply device is disclosed.

JP 2014-150643 A

  As described above, when the image forming apparatus transitions to the power saving state or when the power switch of the image forming apparatus is turned off, the power supply apparatus disconnects the relay and switches from the commercial AC power supply to the switching power supply unit. The operation to stop the power supply is performed. However, the following problem arises when an event of transition to a normal state in which image formation is performed or an operation to turn on the power switch occurs immediately after the power supply device disconnects the relay. In other words, in order to generate voltage in the switching power supply unit, the power supply device connects the relay again and supplies power from the commercial AC power supply to the switching power supply unit. At that time, the relay contact is in a stable state. A predetermined waiting time is required until Furthermore, in the switching power supply unit, it takes time to rectify the input AC voltage, charge the rectified DC voltage to the smoothing capacitor, and increase the output voltage to a predetermined voltage. Become. Therefore, there has been a demand for a power supply device having a configuration capable of transitioning from a power saving state to a normal state in a short time.

  The present invention has been made under such circumstances, and an object thereof is to make a transition from a power saving state to a normal state in a short time.

  In order to solve the above-described problems, the present invention has the following configuration.

  (1) An output unit that generates a DC voltage from an AC voltage and outputs it to a load; a switching unit that switches a connection state between an AC power supply and the output unit; and the switching unit that controls the load unit to control the load A power supply apparatus comprising: control means for supplying and stopping power supply to the power supply; and instruction means for instructing activation and stop of the output means, wherein the control means includes the output means by the instruction means. When a stop instruction is detected, after the first time corresponding to the AC voltage of the AC power source input to the output unit has elapsed, the switching unit disconnects the AC power source from the output unit. A power supply device that stops power supply to the load.

  (2) An image forming apparatus comprising: an image forming unit that forms an image on a recording material; and the power supply device according to (1).

  (3) An output unit that generates a DC voltage from the AC voltage and outputs it to a load, a switching unit that switches a connection state between an AC power source and the output unit, and the switching unit that controls the load unit from the output unit. An image for image formation, comprising: a power supply device having a control unit for supplying and stopping power supply to the image forming apparatus; an image forming unit for forming an image on a recording material; and a controller for controlling the image forming unit. An image forming apparatus operable in a sleep state in which the power consumption is lower than that in the image formation state, and when the controller does not perform image formation, the controller Instructing the control means to stop the output means, and detecting the stop instruction of the output means, the control means responds to the AC voltage of the AC power source input to the output means. After the first period has elapsed the block the connection between the AC power source and said output means by the switching means, the image forming apparatus characterized by stopping the power supply to the load.

  According to the present invention, it is possible to make a transition from the power saving state to the normal state in a short time.

The block diagram which shows the circuit structure of the power supply device of Example 1. FIG. The figure explaining the time data regarding the relay control of Examples 1-3, and the calculation method The flowchart which shows the control sequence which measures time until the switching power supply part of Examples 1-3 stops. The flowchart which shows the control sequence of the relay of Examples 1-3. Time chart explaining the control operation of the power supply device of Examples 1-3 The block diagram which shows the circuit structure of the power supply device of Example 2. FIG. Schematic sectional view of the laser beam printer of Example 3

  Embodiments of the present invention will be described below in detail with reference to the drawings.

[Configuration of power supply unit]
FIG. 1 is a block diagram illustrating a circuit configuration of the power supply device 100 according to the first embodiment. In FIG. 1, an AC voltage input from a commercial AC power supply 1 is supplied to a switching power supply unit 6 via a relay 2. The switching power supply unit 6 that is an output means includes a bridge diode 3, a smoothing capacitor 4, and a switching unit 5. The bridge diode 3 that is a rectifying unit performs full-wave rectification on the AC voltage input from the commercial AC power supply 1, and the DC voltage subjected to full-wave rectification is smoothed by the smoothing capacitor 4. The switching unit 5 converts the DC voltage smoothed by the smoothing capacitor 4 into a DC voltage of the voltage Vcc by a switching operation and outputs it, and the output DC voltage is supplied to a load connected to the power supply device 100. .

  The control unit 7 which is a control means has a configuration in which a CPU (Central Processing Unit) (not shown), ROM and RAM are integrated. The ROM stores operation procedures and data executed by the CPU, and the RAM is used by the CPU to temporarily store information. The control unit 7 may be, for example, a microcomputer including a signal input / output function. In addition, the control unit 7 has a timer 7a for measuring time. A memory 8 serving as a storage unit is a non-volatile memory connected to the control unit 7. The control unit 7 has an IN terminal, a SW terminal, an RLD terminal, and a VDD terminal. The voltage Vcc output from the switching unit 5 is input to the IN terminal, and the control unit 7 can detect the voltage value of the voltage Vcc. In addition, a voltage VDD output from the power storage unit 10 is input to the VDD terminal, and an ON (high level) or OFF (low level) signal is input to the SW terminal according to the state of the switch 13. An RLD signal for controlling the relay 2 is output from the RLD terminal.

  The relay 2 serving as a switching unit is provided in a power supply path between the commercial AC power supply 1 and the switching power supply unit 6, and is connected to or disconnected from the commercial AC power supply 1 to the switching power supply unit 6. Control the input of AC voltage. Switching control of the relay 2 is performed by the relay drive unit 9. An instruction for switching control of the relay 2 is performed according to an RLD signal output from the RLD terminal of the control unit 7 to the relay driving unit 9, and the relay driving unit 9 performs switching control of the relay 2 based on the RLD signal. . The relay 2 may be a latching relay that maintains an on state or an off state even after the supply of operating power is stopped.

  The power storage unit 10 serving as a power storage unit includes a capacitor or the like, and holds the charge by charging the capacitor or the like. The power storage unit 10 is supplied with power from the switching unit 5 and the sub power supply 12, and a voltage VDD for operating the control unit 7 is output to the VDD terminal of the control unit 7. The voltage Vcc output from the switching unit 5 is input to the power storage unit 10 via the diode 11. The diode 11 is provided to prevent a current from flowing backward from the power storage unit 10 to the switching unit 5. Sub power supply 12 is connected to a power supply path between commercial AC power supply 1 and relay 2, and outputs a small amount of power to charge power storage unit 10. The power storage unit 10 is supplied with power from the sub power source 12 when the relay 2 is in an off state (disconnected state). On the other hand, if the relay 2 is in the on state (connected state) and the switching unit 5 of the switching power supply unit 6 outputs the voltage Vcc, power is also supplied from the switching unit 5.

  The switch 13 is a switch that is operated by the user to start or stop the switching power supply unit 6 and functions as an instruction unit that instructs start or stop. The state of the switch 13 is detected by the control unit 7 via the SW terminal. In this embodiment, it is assumed that an ON level is input to the SW terminal when the switch 13 is pressed, and an OFF level is input when the switch 13 is not pressed. When the control unit 7 detects the operation of the switch 13, the power supply device 100 is turned on in the normal state in which the switching power supply unit 6 outputs the voltage Vcc, or in the power saving state in which the switching power supply unit 6 stops its operation. Control to the state. If the power supply apparatus 100 is in the on state, the control unit 7 sets the switching power supply unit 6 in the low power consumption state in which the amount of power supplied to the load is reduced before the switch 13 is switched to the off state. It controls so that it will be in the OFF waiting state which is. When the control unit 7 detects that a predetermined time has elapsed in the off waiting state, the control unit 7 turns off (disconnects) the relay 2 via the relay driving unit 9, so that the commercial AC power supply 1 and the switching power supply unit 6 are connected. The power supply is cut off, and the power supply apparatus 100 is turned off, which is a power saving state.

[Voltage output stop time and relay off waiting time]
FIG. 2A is a diagram illustrating a configuration example of data stored in the memory 8 of the power supply apparatus 100 illustrated in FIG. The data shown in FIG. 2A is a table composed of an input voltage Vac, a Vcc output stop time Toff (hereinafter also referred to as time Toff), and a relay OFF waiting time Tdly (hereinafter also referred to as time Tdly). The input voltage Vac (unit: V) indicates an input voltage value from the commercial AC power supply 1. The time Toff (unit: sec (seconds)) indicates the time from when the control unit 7 turns off the relay 2 via the relay drive unit 9 until the output voltage Vcc of the switching unit 5 drops to a predetermined voltage. . The time Tdly (first time) indicates a time during which the switching power supply unit 6 is maintained in the low power consumption state in the off waiting state before the power supply device 100 is shifted to the off state by the operation of the switch 13. The waiting time Tdly is a time during which the power consumption in the low power consumption state in the off waiting state is equal to the power consumption amount of the power supply apparatus 100 in a predetermined time (for example, 1 hour) in the state where the relay 2 is turned off (OFF power state). Indicates.

  The data shown in FIG. 2A is measured when the power supply apparatus 100 is adjusted, and is set in the memory 8. For example, when the power supply apparatus 100 is adjusted, the power supply apparatus 100 is operated with the input voltage Vac input from the commercial AC power supply 1 set to 85 V, for example, and the voltage Vcc is output from the switching unit 5 To. From this state, the control unit 7 changes the relay 2 from the on state (connected state) to the off state (disconnected state), and resets and starts the timer 7a. Then, when the control unit 7 as the second detection means detects that the voltage value of the voltage Vcc input to the IN terminal has dropped below a predetermined voltage indicating that the voltage output of the switching unit 5 has stopped. The timer 7a is stopped. Then, the control unit 7 reads a timer value (for example, 70 sec) from the timer 7a, sets the read timer value as a time Toff in the table of the memory 8 together with the input voltage Vac.

  Further, the waiting time Tdly until turning off the relay 2 is set to 120 sec so that the power consumption in the OFF waiting state and the average power consumption per unit time in the OFF state of the relay 2 are equal to or less than a predetermined power. Set to 8. Further, the same measurement is performed when the input voltage Vac from the commercial AC power supply 1 is 140 V, and 115 seconds are set in the time Toff and 73 seconds are set in the memory 8 based on the measurement result. The relay OFF waiting time Tdly is measured in advance during power adjustment of the power supply apparatus 100, and the average power in the OFF waiting state in the low power consumption state and the OFF state after the relay 2 is OFF is equal to or less than the predetermined power. The calculation method may be as follows. The time calculation method is not particularly limited.

  Next, FIG. 2B shows a method of determining the off waiting time Tdly until the control unit 7 turns off the relay 2 according to the input voltage Vac of the commercial AC power supply 1 during the operation of the power supply apparatus 100. It explains using. FIG. 2B illustrates the data shown in FIG. 2A. The horizontal axis represents the input voltage Vac (unit: v), and the left vertical axis represents time Toff (unit: sec (seconds)). ), And the vertical axis on the right side indicates time Tdly (unit: sec (seconds)). In the figure, the circled plots show the relationship of the time Toff to the input voltage Vac, and the time Toff when the input voltage Vac is 85V and 140V is 70 sec and 115 sec, respectively. A straight line connecting the two circled plots indicates the correspondence between the input voltage Vac and the time Toff. On the other hand, the square plot shows the relationship of the time Tdly to the input voltage Vac, and the time Tdly when the input voltage Vac is 85 V and 140 V is 120 sec and 73 sec, respectively. A straight line connecting two square plots indicates the correspondence between the input voltage Vac and the time Tdly.

  When power is supplied from the commercial AC power supply 1 to the power supply device 100, the control unit 7 is activated, and the power supply device 100 enters a power-off state in which the voltage Vcc is not output. Thereafter, by operating the switch 13, the relay 2 is connected, the switching power supply unit 6 operates, and a normal state (power-on state) in which the voltage Vcc is output is entered. When the power supply device 100 is changed from the normal state to the power-off state for the first time by operating the switch 13, the control unit 7 performs the following operation. That is, when the control unit 7 turns off the relay 2 via the relay driving unit 9, the power supply path to the commercial AC power supply 1 is cut and the power supply to the switching power supply unit 6 is stopped. As a result, the potential of the smoothing capacitor 4 decreases, and accordingly, the voltage value of the voltage Vcc decreases, and the operation of the switching unit 5 of the switching power supply unit 6 stops. The control unit 7 turns off the relay 2 and starts time measurement by the timer 7a. When the control unit 7 detects that the voltage Vcc input to the IN terminal has dropped below a predetermined voltage, the control unit 7 stops the timer 7a. And the control part 7 reads the timer value at that time, and preserve | saves the read timer value in the memory 8 as time Toff. For example, when the time Toff at this time is 90 sec, in FIG. 2B, the dotted line where the time Toff is 90 sec and the straight line indicating the correspondence between the input voltage Vac and the time Toff intersect. The input voltage Vac becomes the input voltage Vac of the commercial AC power supply 1. Accordingly, the control unit 7 determines that the input voltage Vac when the time Toff is 90 sec is about 110 [V]. In this case, when the input voltage Vac is 110 V, the control unit 7 determines that the time Tdly at the point where the straight line indicating the correspondence relationship between the input voltage Vac and the time Tdly intersects is about 100 seconds.

Here, the method for calculating the input voltage Vac and the time Tdly has been described based on the graph shown in FIG. 2B. However, the input voltage Vac and the time Tdly are calculated by the approximate expression based on the data shown in FIG. You may ask for. For example, in order to obtain the input voltage Vac from the commercial AC power supply 1, the control unit 7 uses the approximate expression (1) for calculating the input voltage Vac based on the data in FIG. You may ask for it.
Input voltage Vac≈1.22 × time Toff−0.56 (1)

Further, for the waiting time Tdly until the relay 2 is turned off, the time Tdly may be obtained using the approximate expression (2) for calculating the time Tdly based on the data in FIG.
Time Tdly≈−0.85 × input voltage Vac + 193 (2)

  In addition, the numerical value of the approximate expression and the data of the time Tdly corresponding to the plurality of input voltages Vac may be set in advance in the memory 8 as a numerical value table, and may be used as necessary when calculating.

[Measurement of output stop time]
FIG. 3 is a flowchart showing a control sequence for calculating the time Toff until the output voltage Vcc of the switching unit 5 falls below a predetermined voltage, and is executed by the control unit 7. In FIG. 3, power is supplied from the commercial AC power supply 1 to the power supply device 100, the relay 2 is turned on (connected) by the operation of the switch 13, and the switching power supply unit 6 operates by the power supply from the commercial AC power supply 1. When the normal state of outputting the voltage Vcc is reached, the operation is started.

  In step (hereinafter referred to as S) 100, the control unit 7 determines whether or not the switch 13 is operated based on a signal level indicating the state of the switch 13 input to the SW terminal. If the controller 7 determines that the switch 13 has been operated, the process proceeds to S101. If the controller 7 determines that the switch 13 has not been operated, the process returns to S100. In S101, the control unit 7 outputs an RLD signal for turning off the relay 2 from the RLD terminal, and switches the relay 2 from the on state (connected state) to the off (OFF) state (disconnected state) via the relay driving unit 9. Switch. Thereby, the power supply from the commercial AC power supply 1 to the switching power supply unit 6 is cut off. In S102, the control unit 7 resets and starts the timer 7a to start measuring the time Toff, which is the Vcc output stop time until the voltage Vcc drops below a predetermined voltage.

  In S103, the control unit 7 detects the voltage value of the voltage Vcc output from the switching unit 5 and input to the IN terminal, and determines whether or not the voltage value has dropped below a predetermined voltage. If the control unit 7 determines that the voltage Vcc has decreased below the predetermined voltage, the control unit 7 proceeds the process to S104. If the control unit 7 determines that the voltage Vcc has not decreased below the predetermined voltage, the control unit 7 proceeds the process to S105. In S104, the control unit 7 stops the timer 7a, stops measuring the time Toff, reads the timer value from the timer 7a, stores the read timer value in the memory 8 as the time Toff, and ends the process. . As described above, the control unit 7 acquires the time Toff based on the detection result of the voltage Vcc input to the IN terminal and the measurement result of the timer 7a.

  In S105, the control unit 7 determines whether or not the switch 13 has been operated based on the signal level indicating the state of the switch 13 input to the SW terminal. If the control unit 7 determines that the switch 13 has been operated, the process proceeds to S106. If the control unit 7 determines that the switch 13 has not been operated, the process returns to S103. In S106, the control unit 7 performs a process of transitioning from the power-off (OFF) state where the switching power supply unit 6 stops outputting the voltage Vcc to the normal state outputting the voltage Vcc. That is, the control unit 7 stops the timer 7a, stops measuring the time Toff, outputs an RLD signal for turning on the relay 2 from the RLD terminal, and turns off the relay 2 via the relay driving unit 9. Switch from (disconnected state) to on (connected state). Thereby, the power supply from the commercial AC power supply 1 to the switching power supply unit 6 is resumed, and the switching power supply unit 6 resumes the switching operation. And the control part 7 returns a process to S100.

[Control of power supply]
In FIG. 4, the time Toff is measured by the control unit 7 shown in FIG. 3, and then the relay 2 is turned on by the operation of the switch 13, and the power supply apparatus 100 is started after the transition to the normal state. 7 is a flowchart of a control sequence executed by 7. In S200, the control unit 7 operates the switch 13 based on the signal level indicating the state of the switch 13 input to the SW terminal in the normal state where the relay 2 is turned on and the switching power supply unit 6 is operating. Determine whether or not. If the controller 7 determines that the switch 13 has been operated, the process proceeds to S201. If the controller 7 determines that the switch 13 has not been operated, the process returns to S200. In S201, the control unit 7 performs a process of transitioning the switching power source unit 6 from the normal state to the OFF (OFF) waiting state of the relay 2 in which the load supplied with power is in the low power consumption state.

  In S202, the control unit 7 calculates the OFF waiting time Tdly of the relay 2 by the method described with reference to FIG. That is, the control unit 7 calculates the input voltage Vac corresponding to the time Toff based on the time Toff stored in the memory 8 and the table data stored in the memory 8, and the time corresponding to the calculated input voltage Vac. Tdly is calculated. Then, the control unit 7 sets the time Tdly, which is the calculated relay-off waiting time, to the timer 7a, and then starts the timer 7a. Here, the timer 7a is a method of subtracting the set time with the passage of time.

  In S203, the control unit 7 refers to the timer value of the timer 7a to determine whether or not the relay-off (OFF) waiting time Tdly has elapsed, that is, whether or not the timer value is 0. When it is determined that the timer value becomes 0 and the time Tdly has elapsed, the control unit 7 advances the process to S204, and when the timer value is not 0, advances the process to S205. In S205, the control unit 7 determines whether or not the switch 13 has been operated based on the signal level indicating the state of the switch 13 input to the SW terminal. If the controller 7 determines that the switch 13 has been operated, the process proceeds to S206. If the controller 7 determines that the switch 13 has not been operated, the process returns to S203. In S206, the control unit 7 performs a process of transitioning the switching power supply unit 6 from the OFF (OFF) waiting state of the relay 2 that is in the low power consumption state to the normal state, and returns the process to S200.

  In S204, since the relay-off (OFF) waiting time Tdly has elapsed, the control unit 7 outputs an RLD signal for turning off the relay 2 from the RLD terminal, and turns on the relay 2 via the relay driving unit 9 (connected state). ) To OFF state (disconnected state). Thereby, the power supply from the commercial AC power supply 1 to the switching power supply unit 6 is cut off, and the output of the voltage Vcc from the switching power supply unit 6 is stopped. In S207, the control unit 7 determines whether or not the switch 13 has been operated based on the signal level indicating the state of the switch 13 input to the SW terminal. If the controller 7 determines that the switch 13 has been operated, the process proceeds to S208. If the controller 7 determines that the switch 13 has not been operated, the process returns to S207. In S208, the control unit 7 performs a process of transitioning from the OFF state where the switching power supply unit 6 stops outputting the voltage Vcc to the normal state outputting the voltage Vcc. That is, the control unit 7 outputs an RLD signal for turning on the relay 2 from the RLD terminal, and switches the relay 2 from the off state (disconnected state) to the on state (connected state) via the relay driving unit 9. Thereby, the power supply from the commercial AC power supply 1 to the switching power supply unit 6 is resumed, and then the switching power supply unit 6 enters a normal state in which the voltage Vcc is output. And the control part 7 returns a process to S200.

  In FIG. 4, when determining whether the relay-off waiting time Tdly has elapsed, it is determined whether the timer value of the timer 7a is 0, but the following method may be used. That is, the timer 7a is reset and started, and when it is detected that the timer value of the timer 7a becomes equal to the relay-off waiting time Tdly, it may be determined that the relay-off waiting time Tdly has elapsed.

[Transition of power supply control]
FIG. 5 is a time chart illustrating the operation of the control unit 7 described in the flowcharts of FIGS. 3 and 4. 5A is a diagram illustrating the state of the switch 13 that is a state transition event. OFF indicates a state in which the switch 13 is not operated, and ON indicates a state in which the switch 13 is pressed. In this embodiment, the controller 7 is operated when the switch 13 is changed from a state where the switch 13 is pressed (ON in the figure) to a state where the switch 13 is not pressed (OFF in the figure). Detect that. (B) is a figure which shows the state of the relay 2, ON shows the state in which the relay 2 is an ON state (connection state) and electric power is supplied to the switching power supply part 6 from the commercial AC power supply 1. FIG. On the other hand, OFF indicates a state in which the relay 2 is in an off state (disconnected state) and the power supply from the commercial AC power source 1 to the switching power source unit 6 is interrupted. (C) is a diagram showing the state of the output voltage of the switching unit 5, the voltage Vcc is a voltage output when the power supply device 100 is in a normal state, and the voltage Vth is the operation of the switching unit 5 is stopped. , A voltage that is a threshold value when it is determined that the voltage output is stopped. (D) has shown the state of the power supply device 100, the normal power which is a 2nd state shows the state in which the voltage Vcc is output from the switching power supply part 6, and the low power consumption which is a 1st state Indicates a low power consumption state in which the relay 2 is waiting to be turned off. Furthermore, the OFF power that is the third state indicates a state in which the relay 2 is turned off and the switching power supply unit 6 stops operating. Note that the horizontal axis indicates time, and t0 to t16 indicate time.

  From time t0 to time t3, the control unit 7 detects that the voltage Vcc input to the IN terminal has decreased to a predetermined voltage Vth by turning off the relay 2 from the normal state via the relay driving unit 9. The time Toff until the switching power supply unit 6 stops outputting is determined. The operation of the control unit 7 at time t0 to time t3 corresponds to the control sequence shown in FIG. From time t4 to time t6, the control unit 7 detects the operation of the switch 13, turns on the relay 2, and causes the power supply device 100 to transition from the OFF power state to the normal power state.

  From time t7 to time t10, when the control unit 7 detects an operation of the switch 13, the control unit 7 maintains the low power consumption state during the OFF waiting time Tdly (time t8 to time t9). Then, when the OFF waiting time Tdly has elapsed, the control unit 7 turns off the relay 2 and makes a transition to the power-off (OFF) state, which is an OFF power state. The operation of the control unit 7 from time t7 to time t10 corresponds to the processing of S201 to S204 in FIG. From time t10 to time t13, when detecting the operation of the switch 13, the control unit 7 turns on the relay 2 and causes the power supply device 100 to transition from the OFF power state to the normal power state. The operation of the control unit 7 from time t10 to time t12 corresponds to the processing of S207 and S208 in FIG. From time t14 to time t16, when the control unit 7 detects the operation of the switch 13, the control unit 7 maintains the low power consumption state during the off waiting time Tdly, and operates the switch 13 at time t16 before the off waiting time Tdly elapses. Is detected, and the power supply device 100 is shifted to the normal power state. The operation of the control unit 7 from time t14 to time t16 corresponds to the processing of S201 to S206 in FIG.

  At time t0, the relay 2 is in an ON state, the switching power supply unit 6 is operating, and the voltage Vcc is being output. At time t1, when the switch 13 is operated (ON operation) and a switch operation that causes the power supply device 100 to transition to the power-off state is detected, the control unit 7 turns off the relay 2 at time t2. Thereby, the power supply from the commercial AC power supply 1 to the switching power supply unit 6 is cut off, and the power supply apparatus 100 transitions from the normal power state to the OFF power state in which only the control unit 7 consumes power. Since the power supply from the commercial AC power supply 1 is cut off, the voltage value of the voltage Vcc output from the switching power supply unit 6 drops to the threshold voltage Vth at time t3. The control unit 7 stores the time from when the relay 2 is turned off to when the output voltage decreases to the voltage Vth, that is, the time from time t2 to time t3 in the memory 8 as time Toff (second time). After time t3, the voltage value of the voltage Vcc output from the switching power supply unit 6 decreases from the voltage Vth to 0V.

  When the switch 13 is operated (ON operation) at time t4 and a switch operation that causes the power supply device 100 to transition to the power-on state is detected, the control unit 7 turns on the relay 2 at time t5. As a result, the power supply path from the commercial AC power supply 1 to the switching power supply unit 6 is connected, the power supply to the switching power supply unit 6 is resumed, and the power supply device 100 transitions from the OFF power state to the normal power state. After time t5, the smoothing capacitor 4 of the switching power supply unit 6 is charged and the switching unit 5 outputs a DC voltage. At time t6, the output voltage value is stabilized at the voltage Vcc. The time from time t4 to time t6 when the output voltage is stabilized at the voltage Vcc after the power supply device 100 is in the OFF power state turns on the relay 2 after detecting the operation of the switch 13, the contact of the relay 2 is stabilized, and the switching power supply It becomes a stabilization waiting time until the output voltage of the unit 6 is stabilized. That is, once the relay 2 is turned off and the switching power supply unit 6 stops the voltage output, a time from time t4 to time t6 is required until the power supply device 100 is changed to the normal state again. .

  At time t7, when the switch 13 is operated (ON operation) to detect a switch operation for shifting to the power off state, the control unit 7 causes the power supply device 100 to transition to the low power consumption state at time t8. And the control part 7 maintains the power supply device 100 in a low power consumption state until time t9 when the waiting time Tdly until turning off the relay 2 elapses. At time t9, the control unit 7 turns off the relay 2. As a result, the power supply apparatus 100 transitions from the normal power state to the OFF power state where only the control unit 7 consumes power. Since power supply from the commercial AC power supply 1 is cut off, the voltage value of the voltage Vcc output from the switching power supply unit 6 drops to the voltage Vth at time t10 when the time Toff has elapsed from time t9. After time t10, the voltage value of the voltage Vcc output from the switching power supply unit 6 decreases from the voltage Vth to 0V.

  When the switch 13 is operated (ON operation) at time t11 and a switch operation that causes the power supply device 100 to transition to the power-on state is detected, the control unit 7 turns on the relay 2 at time t12. Thereby, the power supply from the commercial AC power supply 1 to the switching power supply unit 6 is resumed, and the power supply device 100 transitions from the OFF power state to the normal power state. After time t12, the smoothing capacitor 4 of the switching power supply unit 6 is charged and the switching unit 5 outputs a DC voltage. At time t13, the output voltage value is stabilized at the voltage Vcc. Once the relay 2 is turned off and the switching power supply unit 6 stops operating, a stabilization waiting time from time t11 to time t13 until the voltage Vcc is stabilized after the power supply device 100 is in the OFF power state is required.

  At time t14, when the switch 13 is operated (ON operation) and a switch operation to shift to the power off state is detected, the control unit 7 causes the power supply device 100 to transition to the low power consumption state at time t15. And the control part 7 maintains the power supply device 100 in a low power consumption state until the time when waiting time Tdly until turning off the relay 2 passes. At time t <b> 16, when the control unit 7 operates the switch 13 (ON operation) and detects a switch operation that causes the power supply device 100 to transition to the power-on state, the relay 2 is on and the power supply device 100 is in the low power consumption state Therefore, transition to the normal state is made. At time t16, since the relay 2 is in an on state, the contact of the relay 2 is stabilized after detecting the operation of the switch 13 as in the case of the above-described times t4 and t11, and the switching power supply unit 6 There is no stabilization waiting time until the output voltage becomes stable. On the other hand, when the relay 2 is not waiting to be turned off as in this embodiment, when the switching power supply unit 6 stops operating by turning off the relay 2, the following operation is performed until the power supply device 100 transitions to the normal power state. Such time is required. That is, in order to turn on the relay 2 from the off state, it is necessary to always turn on the relay 2 and to stabilize the voltage Vcc that is the output from the switching power supply unit 6. In addition, every time a transition event to the normal state occurs, it is necessary to switch the relay 2 to the on state, and the number of times the relay is driven becomes larger than in the case of the present embodiment.

  As described above, in the present embodiment, when a switch operation that makes a transition to the power-off state is detected, the timing for disconnecting the relay is delayed while maintaining the low power consumption state. As a result, even when a switch operation for transition to the normal state is performed immediately after the switch operation for transition to the power-off state, the commercial AC power supply is connected to the switching power supply via the relay, so that Such effects can be achieved. In other words, there is no need for the relay ON control and the waiting time until the relay is stabilized, and further, the charging of the smoothing capacitor of the switching power supply unit and the stabilization time of the output voltage are not required, and the power supply device can transition to the normal state in a short time. it can. As a result, the frequency of switching the relay to the on state decreases every time a switch operation that causes the power supply device to transition to the normal state occurs, so that deterioration inside the relay due to the current that flows when the relay is turned on can be reduced. .

  By the way, the power supply apparatus 100 of a present Example does not have the voltage detection means which detects the input voltage Vac of the commercial alternating current power supply 1. FIG. Therefore, the control unit 7 calculates the input voltage Vac based on the time Toff obtained by the control sequence shown in FIG. 3 and the table data stored in the memory 8. For example, when the power supply device 100 has voltage detection means (first detection means) for detecting the input voltage Vac of the commercial AC power supply 1, the control unit 7 receives the input voltage via the voltage detection means. By acquiring Vac, it is not necessary to perform the control sequence shown in FIG. Therefore, when the power supply device 100 is shifted to the OFF state by operating the switch 13, the control unit 7 indicates the correspondence relationship between the detected input voltage Vac, the input voltage Vac stored in the memory 8, and the time Tdly. Based on the data, the time Tdly can be determined. As a result, when the control unit 7 changes the power supply device 100 to the off state, the control unit 7 can always change the power supply device 100 to the low power consumption state in the relay-off waiting state before changing from the on state to the off state. it can.

  In the present embodiment, the switch 13 operated by the user has been described as an instruction unit for instructing activation or stop of the power supply device. However, apart from the switch 13, the instruction unit may be instructed by an instruction signal from an external device (for example, a computer). Alternatively, the time set to the timer in the CPU may be counted and the timing when it becomes zero may be used as a trigger.

  As described above, according to the present embodiment, it is possible to make a transition from the power saving state to the normal state in a short time.

  In the first embodiment, a relay is used as a switching means for connecting and disconnecting the power supply path between the commercial AC power supply 1 and the switching power supply unit 6, but in the second embodiment, a bidirectional thyristor (semiconductor element) ( Hereinafter, an example using triac) will be described.

[Configuration of power supply unit]
FIG. 6 is a block diagram illustrating a circuit configuration of the power supply device 100 according to the second embodiment. A difference from FIG. 1 according to the first embodiment is a circuit that connects and disconnects the commercial AC power supply 1 and the switching power supply unit 6. It is a configuration. In FIG. 6, a semiconductor device triac 20 is a switching means provided between the commercial AC power supply 1 and the bridge diode 3 of the switching power supply unit 6. When the triac 20 is turned on (conductive state), the AC voltage from the commercial AC power supply 1 is input to the bridge diode 3, whereby electric power is supplied to the switching power supply unit 6. As a result, the switching unit 5 The voltage Vcc is output. On the other hand, when the triac 20 is turned off (non-conducting state), the power supply from the commercial AC power supply 1 to the switching power supply unit 6 is stopped. As a result, the switching unit 5 stops operating and the voltage Vcc is reduced. Output is stopped.

  The triac drive unit 21 is a drive unit that switches an on state and an off state of the triac 20, and the triac drive unit 21 performs switching control of the triac 20. The instruction for the switching control of the triac 20 is performed according to the RLD signal output from the RLD terminal of the control unit 7 to the triac driving unit 21, and the triac driving unit 21 performs the switching control of the triac 20 based on the RLD signal. . The other configuration of the power supply device 100 is the same as that of the first embodiment, and the same components are denoted by the same reference numerals as those of the first embodiment, and the description thereof is omitted here.

  The triac drive unit 21 is connected to the power storage unit 10 and is supplied with power from the power storage unit 10 even when the triac 20 is in an off state (non-conducting state) and the switching power supply unit 6 is in an off state. 20 controls can be performed. The triac drive unit 21 is also configured to be supplied with power from the sub power source 12 via the power storage unit 10. Therefore, even if the triac 20 is in the off state and the switching power supply unit 6 is in the off state, the control unit 7 can drive the triac 20 via the triac drive unit 21.

  As described above, when the operation of the switch 13 for transitioning to the power-off state is detected when the power supply device 100 is operating in the normal state as described in the present embodiment, the triac 20 remains in the low power consumption state. The off-waiting state for delaying the off-state is set. As a result, even if a switch operation that causes the power supply apparatus 100 to transition to the normal state occurs immediately after detecting the operation of the switch 13 that causes the power supply to transition to the power-off state, the TRIAC 20 is in the on-state, so that it can quickly transition to the normal state. Can do. Even when the triac 20 is used, the control sequences shown in FIGS. 3 and 4 of the first embodiment can be applied to the triac 20 by replacing the control for the relay 2 with the control for the triac 20.

  As described above, according to the present embodiment, it is possible to make a transition from the power saving state to the normal state in a short time.

  In the third embodiment, an embodiment in which the power supply apparatus 100 described in the first and second embodiments is applied to a laser beam printer 200 that is an example of an image forming apparatus will be described.

[Configuration of Image Forming Apparatus]
FIG. 7 is a schematic cross-sectional view of the laser beam printer 200 according to the third embodiment. The laser beam printer 200 includes a power supply device 100, and a switch 13 that is a main switch of the image forming apparatus is connected to the power supply device 100. The switch 13 is a power switch of the laser beam printer 200, and is also a power switch that is operated when the power supply apparatus 100 transitions to an OFF state or an ON state. It is assumed that the power supply apparatus 100 has the configuration shown in FIG. The controller 201 is a control unit that controls the laser beam printer 200. The controller 201 is, for example, a CPU, and includes a ROM that holds procedures and data for controlling the operation of the CPU, a RAM that temporarily holds information, and an individually equivalent function. A circuit is connected. The controller 201 may be a microcomputer including a timer function that measures time, for example.

  The controller 201 controls the image forming operation by receiving a print instruction event from an external computer or the like. When the controller 201 receives the print instruction event, the controller 201 transports a recording material, which is a recording medium for recording an image stacked on the paper feed cassette 213, to the transport path by the pickup roller 203 and aligns the leading ends of the recording materials 202. Transport to. An image forming unit 205 as an image forming unit forms an image on the conveyed recording material 202 by a known electrophotographic process. The image forming unit 205 includes an irradiation unit 205a, a photosensitive drum 205b, a developing unit 205c, and a transfer member 205d. The irradiating unit 205a forms a latent image on the photosensitive drum 205b of an image image in the electrophotographic process, and the developing unit 205c attaches toner to the latent image on the photosensitive drum 205b to form a toner image. The transfer member 205d transfers the toner image formed on the photosensitive drum 205b onto the recording material 202 conveyed from the registration roller 204.

  A fixing unit 206 serving as a fixing unit heats and pressurizes the toner image transferred onto the recording material 202 and fixes the toner image on the recording material 202. Then, the recording material 202 that has passed through the fixing unit 206 is discharged by a paper discharge roller 207 to a paper discharge tray 208 that is provided above the laser beam printer 200 and on which the discharged recording material 202 is stacked. The pickup roller 203, the registration roller 204, and the paper discharge roller 207 constitute a conveying unit that conveys the recording material 202. The motor 210 drives each part of the pickup roller 203, the registration roller 204, and the image forming unit 205 that convey the recording material 202, and the motor 211 drives each part of the fixing unit 206. The motors 210 and 211 are driven by power supply from the power supply apparatus 100.

  The controller 201 performs control to change the operation state so that the laser beam printer 200 can operate in an image forming state in which an image is formed on the recording material 202 or a sleep state that is a power saving state. The controller 201 has an automatic OFF mode in which the power supply apparatus 100 is shifted to the OFF state in order to shift to the sleep state when a predetermined time has elapsed without image formation. The controller 201 transitions the power supply apparatus 100 to the power supply apparatus 100 via the signal path 214 to transition the power supply apparatus 100 to the OFF state when a predetermined time elapses without image formation. An instruction signal to be output is output. Furthermore, the controller 201 stops the operation of loads that are driven during image formation, such as the motors 210 and 211, the image forming unit 205, and the fixing unit 206, in order to reduce power consumption in the laser beam printer 200. In response to the instruction signal from the controller 201, the control unit 7 of the power supply apparatus 100 makes the load during the waiting time Tdly until the switching power supply unit 6 is shifted to the low power consumption state and the relay 2 is turned off. Reduce power supply and maintain low power consumption. When the time Tdly elapses, the control unit 7 turns off the relay 2, stops the operation of the switching power supply unit 6, puts the power supply device 100 in the power-off state, and causes the laser beam printer 200 to transition to the sleep state. Thereby, the power consumption in the laser beam printer 200 which is an image forming apparatus can be reduced.

  If the controller 201 outputs an instruction signal for causing the power supply apparatus 100 to transition to the off state and the controller 201 receives a print instruction for performing an image forming operation before the power supply apparatus 100 transitions to the off state, In the embodiment, the same effects as those of Embodiments 1 and 2 can be obtained. That is, in this embodiment, the power supply apparatus 100 is in a relay-off waiting state in which the relay 2 is delayed in a low power consumption state for a predetermined time Tdly before the relay 2 is turned off. Therefore, when the controller 201 receives a print instruction during the relay-off waiting state, the power supply apparatus 100 continues to output the voltage Vcc from the switching power supply unit 6 without turning off the relay 2, and returns to the normal state. Transition can be made. As a result, the laser beam printer 200 shifts to a normal state in which an image forming operation can be performed in a short time in the case of the present embodiment as compared with the case of the power supply device that does not have a relay-off waiting state and turns off the relay 2. Can be made.

  As described above, according to the present embodiment, it is possible to make a transition from the power saving state to the normal state in a short time.

DESCRIPTION OF SYMBOLS 1 Commercial alternating current power supply 2 Relay 6 Switching power supply part 7 Control part 13 Switch 100 Power supply device

Claims (24)

Output means for generating a DC voltage from the AC voltage and outputting it to a load;
Switching means for switching the connection state between the AC power source and the output means;
Control means for controlling the switching means to supply and stop power supply from the output means to the load;
Instruction means for instructing activation and stop of the output means;
A power supply device comprising:
When the control means detects an instruction to stop the output means by the instruction means, the switching means after the first time corresponding to the AC voltage of the AC power source input to the output means has elapsed. The power supply device is characterized in that the connection between the AC power supply and the output means is interrupted to stop the power supply to the load. A power storage means for storing power supplied from the AC power supply and the output means;
The power storage device according to claim 1, wherein the power storage unit supplies power to the control unit and the switching unit.   The said control means changes the said output means to the 1st state which reduced the electric power supply amount to the said load, if the instruction | indication of the stop of the said output means by the said instruction means is detected. The power supply device according to claim 1 or 2.   When the control means detects an instruction to start the output means by the instruction means before the first time elapses, the AC power source by the switching means and the output means are connected, The power supply apparatus according to claim 3, wherein the output unit transitions from the first state to a second state that does not reduce the amount of power supplied to the load.   The first time is a time during which the power consumption of the power supply device in the first state is equal to the amount of power consumed by the power supply device in a predetermined time in the third state in which the output means is stopped. The power supply device according to claim 4, wherein: A storage means,
The information on the AC voltage input from the AC power supply and the information on the first time corresponding to the AC voltage are stored in the storage means. Power supply. Comprising first detecting means for detecting the AC voltage input from the AC power source;
The control means acquires the AC voltage from the first detection means, and based on the acquired AC voltage, the AC voltage information stored in the storage means, and the first time information. The power supply device according to claim 6, wherein the first time is determined. The storage means is configured to receive information on the AC voltage input from the AC power supply and a voltage output by the output means after the connection between the AC power supply and the output means is interrupted by the switching means. Memorize the information of the second time until it drops below the voltage,
The control means includes second detection means for detecting a voltage output from the output means, and measurement means for measuring time.
The second time is acquired based on the detection result by the second detection unit and the measurement result by the measurement unit, and the acquired second time and the AC voltage information stored in the storage unit The power supply apparatus according to claim 6, wherein the AC voltage is determined based on the second time information.   The control means determines the first time based on the determined AC voltage and the information on the AC voltage and the information on the first time stored in the storage means. The power supply device according to claim 8.   The power supply apparatus according to claim 1, wherein the instruction unit includes any one of a switch operated by a user, an instruction signal from an external device, or a timer.   The power supply apparatus according to claim 1, wherein the switching unit is a relay.   The power supply apparatus according to claim 1, wherein the switching unit is a bidirectional thyristor. Image forming means for forming an image on a recording material;
A power supply device according to any one of claims 1 to 12,
An image forming apparatus comprising: Output means for generating a DC voltage from the AC voltage and outputting it to a load;
Switching means for switching the connection state between the AC power source and the output means;
Control means for controlling the switching means to supply and stop power supply from the output means to the load;
A power supply unit having
Image forming means for forming an image on a recording material;
A controller for controlling the image forming means;
An image forming state in which image formation is performed, and an image forming apparatus operable in a sleep state with less power consumption than the image forming state,
When the controller does not perform image formation, the controller instructs the control unit to stop the output unit in order to transition to the sleep state.
When the control means detects an instruction to stop the output means, after the first time corresponding to the AC voltage of the AC power input to the output means has elapsed, the control means An image forming apparatus characterized in that the connection to the output means is cut off and the power supply to the load is stopped. The power supply device includes power storage means for storing power supplied from the AC power supply and the output means,
The image forming apparatus according to claim 14, wherein the power storage unit supplies power to the control unit and the switching unit.   16. The control unit, when detecting an instruction to stop the output unit, causes the output unit to transition to a first state in which a power supply amount to the load is reduced. The image forming apparatus described in 1.   When the control means detects an instruction to start the output means from the controller before the first time elapses, the output means remains connected to the AC power source by the switching means and the output means. 17. The image forming apparatus according to claim 16, wherein the means is changed from the first state to a second state that does not reduce the amount of power supplied to the load.   The first time is a time during which the power consumption of the power supply device in the first state is equal to the amount of power consumed by the power supply device in a predetermined time in the third state in which the output means is stopped. The image forming apparatus according to claim 16, wherein the image forming apparatus is an image forming apparatus. The power supply device includes storage means,
The information on the AC voltage input from the AC power supply and the information on the first time corresponding to the AC voltage are stored in the storage means. Image forming apparatus. The power supply device includes first detection means for detecting the AC voltage input from the AC power supply,
The control means acquires the AC voltage from the first detection means, and based on the acquired AC voltage, the AC voltage information stored in the storage means, and the first time information. The image forming apparatus according to claim 19, wherein the first time is determined. The storage means is configured to receive information on the AC voltage input from the AC power supply and a voltage output by the output means after the connection between the AC power supply and the output means is interrupted by the switching means. Memorize the information of the second time until it drops below the voltage,
The control means includes second detection means for detecting a voltage output from the output means, and measurement means for measuring time.
The second time is acquired based on the detection result by the second detection unit and the measurement result by the measurement unit, and the acquired second time and the AC voltage information stored in the storage unit The image forming apparatus according to claim 19, wherein the AC voltage is determined based on the second time information.   The control means determines the first time based on the determined AC voltage and the information on the AC voltage and the information on the first time stored in the storage means. The image forming apparatus according to claim 21.   23. The image forming apparatus according to claim 14, wherein the switching unit is a relay.   23. The image forming apparatus according to claim 14, wherein the switching unit is a bidirectional thyristor.

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