JP2023098223A - Image formation apparatus - Google Patents

Abstract

To provide an image formation apparatus which can suppress the power consumption.SOLUTION: An image formation apparatus (1) comprises: an image formation unit (70); a power source substrate (40) which has a main power source circuit (41) that converts the AC voltage supplied from a commercial AC power source (AC) to a first DC voltage (DV1) and outputs the first DC voltage and a sub power source circuit (42) that converts the AC voltage supplied from the commercial AC power source into a second DC voltage (DV2) and outputs the second DC voltage; a controller substrate (50) which has a main controller (51) that is driven on the basis of the first DC voltage; and an engine substrate (60) which has an engine controller (61) that is driven on the basis of the first DC voltage and controls the image formation unit and a sub controller (62) that is driven on the basis of the second DC voltage and outputs an on/off signal to the main power source circuit of the power source substrate. The engine substrate is arranged so as to be close to the power source substrate with respect to the controller substrate.SELECTED DRAWING: Figure 3

Description

The present invention relates to an image forming apparatus such as a printer.

The image forming apparatus of Patent Document 1 has an image forming section, a main ASIC, a sub ASIC, a power supply section, and a sub power supply circuit. In the image forming apparatus, the image forming section and the main ASIC are driven by power output from the power supply section, and the sub ASIC is driven by power output from the sub power supply circuit. The sub ASIC performs on/off instructions to the power supply section, detection of a detection signal from the power supply section indicating whether or not the voltage is equal to or higher than the voltage required to drive the main ASIC, and detection of on/off of the power switch. The sub ASIC transmits a start signal or a stop signal to the power supply unit and transmits a reset signal or a reset release signal to the main ASIC according to the detection results.

JP 2019-84699 A

In the image forming apparatus, two printed circuit boards are used separately from the power supply board on which the main power supply circuit and the sub power supply circuit are arranged. An engine controller and a sub-controller may be arranged on the engine board, which is a board.

The main controller has a function of controlling LAN and wireless communication, connection with an external device through a USB connector, and the like. The engine controller is provided with a function of controlling the image forming section. The sub-controller is driven by power from the sub-power supply circuit and controls on/off of the main power supply circuit.

In the above configuration, the engine board has an engine controller that controls a large number of electric parts that constitute the image forming section, and instantaneous power consumption is greater than that of the controller board. In addition, since the sub-controller arranged on the engine board is driven by the power from the sub-power supply circuit, it was necessary to suppress the power consumption.

An object of the present disclosure is to provide an image forming apparatus capable of suppressing power consumption.

To solve the above problems, an image forming apparatus according to an aspect of the present invention converts an AC voltage supplied from an image forming unit and a commercial power supply through a first power line into a first DC voltage, A power supply comprising: a main power supply circuit for outputting a first DC voltage; and a sub-power supply circuit for converting an AC voltage supplied from the commercial power supply through a second power supply line into a second DC voltage and outputting the second DC voltage. a substrate, a controller substrate having a main controller driven based on the first DC voltage, an engine controller driven based on the first DC voltage and controlling the image forming unit, and a controller substrate based on the second DC voltage. and a sub-controller that outputs an on/off signal to a main power supply circuit of the power supply board, wherein the engine board is arranged closer to the power supply board than the controller board. ing.

According to the above configuration, the engine board is arranged closer to the power supply board than the controller board. As a result, the wiring from the main power supply circuit mounted on the power supply board to the engine controller mounted on the engine board is shortened, so that power consumption in the wiring can be suppressed. Moreover, since the wiring from the sub-power supply circuit mounted on the power supply board to the sub-controller mounted on the engine board is shortened, power consumption in the wiring can be suppressed.

In the image forming apparatus according to one aspect of the present invention, the controller board and the engine board are arranged so that their board surfaces are parallel to each other, and the power supply board and the controller board are connected to the engine board. They may be arranged on opposite sides of each other.

According to the above configuration, since the controller board, the engine board, and the power supply board are arranged in this order, the engine board can be arranged closer to the power supply board than the controller board.

In the image forming apparatus according to an aspect of the present invention, the controller board and the engine board are arranged such that their board surfaces are included in the same plane, and the power supply board and the controller board are arranged in the same plane as the engine board. They may be arranged on opposite sides of each other with the substrate interposed therebetween.

According to the above configuration, since the controller board, the engine board, and the power supply board are arranged in this order, the engine board can be arranged closer to the power supply board than the controller board.

In the image forming apparatus according to an aspect of the present invention, the sub-power supply circuit includes a first capacitor connected to one end of the commercial power supply, a second capacitor connected to the other end of the commercial power supply, and a second capacitor connected to the other end of the commercial power supply. a rectifying/smoothing circuit that rectifies and smoothes the AC voltage applied to the capacitor and the second capacitor to generate the second DC voltage, wherein the sub-controller is generated by the rectifying/smoothing circuit. It may be driven by the second DC voltage.

According to the above configuration, a stable DC voltage can be supplied to the sub-controller by the rectifying/smoothing circuit of the sub-controller.

In the image forming apparatus according to an aspect of the present invention, the engine board has a power storage element that stores power by the second DC voltage generated by the sub power supply circuit, and the sub controller is configured to While connected to the second power supply line, the power storage element is driven by the second DC voltage output by the sub-power supply circuit, and in a state where the commercial power supply is not connected to the second power supply line, the power storage element It may be driven by the output voltage.

According to the above configuration, even if the commercial power supply is not connected to the second power supply line, the sub-controller outputs the voltage output by the storage element that stored power when the commercial power supply was connected to the second power supply line. , the driving state can be continued.

In the image forming apparatus according to one aspect of the present invention, the controller board has a DC/DC converter that converts the first DC voltage into a third DC voltage and outputs the third DC voltage to the main controller. , the DC/DC converter outputs a detection signal indicating whether or not the third DC voltage is equal to or higher than the voltage required to drive the main controller; When shifting to the ON state, outputting an ON signal to the main power supply circuit, receiving the detection signal, and when the detection signal indicates that the third DC voltage is equal to or higher than the required voltage, The main controller may be instructed to start control.

According to the above configuration, when the main power circuit transitions from the off state to the on state, for example, when the power key is turned on, the main power circuit is turned on and the main controller initiates control. Since it receives instructions, it can be driven by the main controller.

In the image forming apparatus according to one aspect of the present invention, the sub-controller instructs the main controller to stop control when the main power supply circuit transitions from an on state to an off state, and the main controller and executing an off-preparation process in response to the stop instruction from the sub-controller, and after completing the off-preparation process, instructing the sub-controller to shift the main power supply circuit from the on state to the off state. and the sub-controller may output an off signal to the main power supply circuit in accordance with the transition instruction.

According to the above configuration, when the main power circuit changes from the on state to the off state, for example, when the power key is turned off, the main power circuit is turned off, so that the main controller can stop. can.

In the image forming apparatus according to one aspect of the present invention, the main controller instructs the engine controller to stop control in response to the instruction to stop from the sub-controller, and the engine controller controls the main controller. The main controller executes off-preparation processing for the engine controller in response to the stop instruction from the controller, and after completing the off-preparation processing for itself and the engine controller, the main controller instructs the sub-controller to An instruction may be given to shift the main power supply circuit from the ON state to the OFF state.

According to the above configuration, the main controller can be stopped together with the engine controller.

In the image forming apparatus according to one aspect of the present invention, the sub-controller instructs the main controller to stop control when the main power supply circuit transitions from an on state to an off state, and the main controller and instructing the engine controller to stop control in response to the stop instruction from the sub-controller, and the engine controller performs an off preparation process for the engine controller in response to the stop instruction from the main controller. After the engine controller completes the off-preparation process, the sub-controller may be instructed to shift the main power supply circuit from the on state to the off state.

According to the above configuration, after the engine controller completes the off-preparation process, the engine controller instructs the sub-controller to shift the main power supply circuit from the on state to the off state. Therefore, it is possible to eliminate the need for a signal line for transmitting an instruction to shift the main power supply circuit from the ON state to the OFF state from the main controller of the controller board to the sub-controller of the engine board.

According to one aspect of the present invention, it is possible to provide an image forming apparatus capable of suppressing power consumption.

2 is a schematic side cross-sectional view showing the internal configuration of the image forming apparatus; FIG. 1 is a diagram showing an overview of the configuration of an image forming apparatus; FIG. 2 is a block diagram showing a substrate configuration of the image forming apparatus; FIG. 3 is a block diagram showing details of a power board and an engine board; FIG. 4 is a sequence chart showing processing when the image forming apparatus is started. 4 is a sequence chart showing processing when the image forming apparatus ends. 1 is a diagram showing an overview of the configuration of an image forming apparatus; FIG. 2 is a block diagram showing a substrate configuration of the image forming apparatus; FIG. 4 is a sequence chart showing processing when the image forming apparatus ends.

An embodiment of the present invention will be described in detail below. For convenience of explanation, the same members are given the same reference numerals, and their names and functions are also the same. Therefore, detailed description thereof will not be repeated.

(Overall Configuration of Image Forming Apparatus 1)
FIG. 1 is a schematic side sectional view showing the internal configuration of the image forming apparatus 1. As shown in FIG. In the following description, the terms "upper", "lower", "front", "rear", "right", and "left" of the image forming apparatus 1 are appropriately indicated in each figure such as FIG. The directions of the arrows correspond respectively.

As shown in FIG. 1, the image forming apparatus 1 is an LED color printer that forms color images with four color developers consisting of yellow Y, magenta M, cyan C, and black K. As shown in FIG.

In the following description, when distinguishing each component by color, the symbol for each component will be suffixed with "Y" for yellow, "M" for magenta, "C" for cyan, and "" for black. K” shall be attached. In addition, when the components are not distinguished by color, the above-mentioned "Y", "M", "C" and "K" denoting each color are omitted. In FIG. 1, each component is distinguished by color, and the above-described "Y", "M", "C" and "K" are added to the end of the reference numerals of the components.

However, the image forming apparatus 1 is not limited to an LED color printer, and may be, for example, a laser color printer, a facsimile machine, or a so-called multifunctional machine having a printer function and a reading function.

As shown in FIG. 1 , the image forming apparatus 1 has a housing 2 . A paper feed tray 4 on which sheets 3 are stacked is provided at the bottom of the housing 2 . A pickup roller 5 is provided above the front end of the paper feed tray 4 . As the pickup roller 5 rotates, the uppermost sheet 3 in the paper feed tray 4 is delivered to the separation roller 71 .

The sheets 3 are separated one by one between the separation roller 71 and a separation pad (not shown) and conveyed toward the conveying roller 72 . Thereafter, the sheet 3 is conveyed onto the belt unit 11 via the conveying path after the position of the front end is regulated by the registration rollers 6 whose rotation is stopped.

A paper feed sensor 9 , a pre-registration sensor 8 , and a post-registration sensor 7 are provided on the conveying path to detect the passage of the sheet 3 . The paper feed sensor 9 is arranged downstream of the pickup roller 5 and the separation roller 71 in the direction in which the sheet 3 is conveyed. The pre-registration sensor 8 is arranged downstream of the paper feed sensor 9 and the conveying roller 72 and upstream of the registration roller 6 in the conveying direction of the sheet 3 . The post-registration sensor 7 is arranged downstream of the registration roller 6 and upstream of the photosensitive drum 28Y in the sheet 3 conveying direction.

The belt unit 11 has a structure in which an annular belt 13 is stretched between a belt supporting roller 12A arranged on the front side and a belt driving roller 12B arranged on the rear side. Inside the belt 13, transfer rollers 14Y to 14K are provided at positions facing the photosensitive drums 28Y to 28K corresponding to the four process portions 19Y to 19K, respectively, with the belt 13 interposed therebetween.

The belt drive roller 12B is connected to a process motor (not shown) provided inside the housing 2 via a gear mechanism (not shown) when the belt unit 11 is mounted inside the housing 2 . Then, the belt drive roller 12B is driven to rotate by the power of the process motor, so that the belt 13 circulates in the illustrated clockwise direction, whereby the sheet 3 on the upper surface of the belt 13 is conveyed backward.

Above the belt unit 11, exposure sections 17Y to 17K corresponding to the four process sections 19Y to 19K are arranged in the front-rear direction. The exposure units 17Y to 17K are supported on the lower surface of the cover 2A, and have LED heads 18Y to 18K each having a plurality of LEDs arranged in a row at the lower end of each. The exposure unit 17 is controlled to emit light based on image data to be formed, and irradiates the surface of the photosensitive drum 28 with light from the LED head 18 line by line. perform exposure.

Each of the process units 19Y to 19K includes cartridge frames 21Y to 21K, developing cartridges 22Y to 22K detachably attached to each of the cartridge frames 21Y to 21K, photosensitive drums 28Y to 28K, and chargers 29Y to 29K. 29K. When the cover 2A is opened, the exposure section 17 is retracted upward together with the cover 2A, and the processing section 19 can be individually attached to and detached from the housing 2 .

Each of the developer cartridges 22Y to 22K includes developer storage chambers 23Y to 23K that store developer of each color, and supply rollers 24Y to 24K, development rollers 25Y to 25K, and layer thickness regulating blades 26Y to 26Y. It has 26K.

The developer discharged from the developer storage chamber 23 is supplied onto the developing roller 25 by the rotation of the supply roller 24 and is positively triboelectrically charged between the supply roller 24 and the developing roller 25 . Further, the developer supplied onto the developing roller 25 enters between the layer thickness regulating blade 26 and the developing roller 25 as the developing roller 25 rotates, where it is sufficiently triboelectrically charged and It is carried on the developing roller 25 as a thin layer of thickness.

Under the cartridge frame 21, a photosensitive drum 28 whose surface is covered with, for example, a positively charged photosensitive layer, and a charger 29 are provided. During image formation, the photoreceptor drum 28 is rotationally driven, and the surface of the photoreceptor drum 28 is uniformly positively charged by the charger 29 accordingly. Then, the positively charged portion is exposed by scanning of the exposure unit 17 to form an electrostatic latent image on the surface of the photosensitive drum 28 .

Next, the developer borne on the developing roller 25 and positively charged is supplied to the electrostatic latent image on the surface of the photoreceptor drum 28, whereby the electrostatic latent image on the photoreceptor drum 28 is visualized. Thereafter, the developer image carried on the surface of photoreceptor drum 28 is transferred to the negative polarity applied to transfer roller 14 while sheet 3 passes through the nip position between photoreceptor drum 28 and transfer roller 14 . are sequentially transferred onto the sheet 3 by the transfer voltage of . The sheet 3 onto which the developer image has been transferred is then conveyed to a fixing section 31 having a heater 31A.

The fixing unit 31 includes a heating roller 33 having a heater 31A, a pressure roller 32 for pressing the sheet 3 toward the heating roller 33, and a third thermistor 36. The developer image transferred onto the sheet 3 is is heat-fixed on the paper. Thereafter, the sheet 3 heat-fixed by the fixing section 31 is conveyed upward and discharged onto the upper surface of the cover 2A. near the heating roller 33; A third thermistor 36 is arranged. A third thermistor 36 detects the temperature of the heating roller 33 .

The image forming apparatus 1 includes a fan 10 for ventilating the inside of the image forming apparatus 1 and a duct 10A provided with a ventilation opening above the paper feed tray 4 . In the image forming apparatus 1, heat is generated from the fixing section 31, the processing section 19, and the like during image formation. The fan 10 has a function of lowering the temperature inside the image forming apparatus 1 by allowing outside air to flow into the image forming apparatus 1 in order to suppress the temperature rise inside the image forming apparatus 1 due to the generated heat.

(Substrate Arrangement of Image Forming Apparatus 1)
FIG. 2 is a diagram showing an overview of the configuration of the image forming apparatus 1. As shown in FIG. FIG. 2A is a diagram showing an overview of the internal configuration of the image forming apparatus 1 as viewed from above. FIG. 2B is a diagram showing an outline of the internal configuration of the image forming apparatus 1 as seen from the left side.

FIG. 2A is a diagram showing an overview of the internal configuration of the image forming apparatus 1 as viewed from above. The image forming apparatus 1 includes a power board 40 , a controller board 50 , an engine board 60 , and an image forming section 70 in the housing 2 . Details of each substrate will be described later.

Further, the image forming apparatus 1 includes a resin frame JF, drive system members KB such as clutches and gears, two sheet metal frames BF, and a fan 10 . The photosensitive drums 28K, 28C, 28M, and 28Y, which constitute the image forming section 70, are pivotally supported between two sheet metal frames BF and driven to rotate by a driving system member KB.

As shown in FIG. 2A, in the image forming apparatus 1, the controller board 50 and the engine board 60 are arranged such that the board surface 501 of the controller board 50 and the board surface 601 of the engine board 60 are parallel to each other. are placed in In this case, the controller board 50 and the engine board 60 are connected by a board-to-board connector. The power supply board 40 and the controller board 50 are arranged on opposite sides of each other with the engine board 60 interposed therebetween.

As shown in FIG. 2B , in the image forming apparatus 1 , the controller board 50 and the engine board 60 overlap each other. Close to the power board 40 .

As shown in FIGS. 2A and 2B, in the image forming apparatus 1, the power supply board 40 includes a board surface 401 of the power supply board 40, a board surface 501 of the controller board 50, and an engine board 60. The substrate surface 601 is arranged so as to be perpendicular to each other.

According to the above, the engine board 60 is arranged closer to the power supply board 40 than the controller board 50 is. As a result, the engine board 60, which instantaneously consumes more power than the controller board 50, is closer to the power supply board 40, so that the wiring between the boards is shortened. Sufficient power can be supplied from 40 to the engine board 60 . Moreover, when the sub-controller 62 of the engine board 60 is driven by the power from the sub-power supply circuit 42 of the power supply board 40, the wiring between the boards is shortened, so that the power consumption due to the wiring can be suppressed.

(Substrate Configuration of Image Forming Apparatus 1)
FIG. 3 is a block diagram showing the substrate configuration of the image forming apparatus 1. As shown in FIG. As shown in FIG. 3, the image forming apparatus 1 further includes an operation panel 80. As shown in FIG.

<Power supply board 40>
The power supply board 40 has a main power supply circuit 41 and a sub power supply circuit 42 .

The main power supply circuit 41 converts an AC voltage supplied from an external commercial AC power supply AC through a first power supply line PL1 into a first DC voltage DV1, and outputs the first DC voltage DV1. The commercial AC power supply AC is, for example, a 100V AC power supply.

The sub power supply circuit 42 converts an AC voltage supplied from an external commercial AC power supply AC through a second power supply line PL2 into a second DC voltage DV2, and outputs the second DC voltage DV2. The first power line PL1 and the second power line PL2 are, for example, power cords.

<Controller board 50>
The controller board 50 has a main controller 51 , a third DC/DC converter 52 , a fourth DC/DC converter 53 , a USB interface 54 and a LAN interface 55 .

The main controller 51 is driven by the third DC voltage DV3 output by the fourth DC/DC converter 53. The third DC/DC converter 52 converts the first DC voltage DV1 output by the main power supply circuit 41 into a first intermediate DC voltage MDV1, and outputs the first intermediate DC voltage MDV1 to the fourth DC/DC converter 53. The fourth DC/DC converter 53 converts the first intermediate DC voltage MDV1 output by the third DC/DC converter 52 into a third DC voltage DV3 and outputs the third DC voltage DV3 to the main controller 51 .

The third DC/DC converter 52 and the fourth DC/DC converter 53 convert the first DC voltage DV1 output by the main power supply circuit 41 into a third DC voltage DV3, and send the third DC voltage DV3 to the main controller 51. It corresponds to a DC/DC converter for output.

The USB interface 54 controls USB connection with external devices. The LAN interface 55 controls LAN communication.

<Engine board 60>
The engine board 60 has an engine controller 61 , a sub-controller 62 , a first DC/DC converter 63 , a second DC/DC converter 64 and an electric storage element circuit 65 .

The engine controller 61 is driven by the fourth DC voltage DV4 output from the second DC/DC converter 64 and controls the image forming section 70 . The sub-controller 62 is driven by the second DC voltage DV2 output by the sub-power supply circuit 42 and outputs an on/off signal to the main power supply circuit 41 of the power supply board 40 . The on/off signal is a signal indicating on or off.

The first DC/DC converter 63 converts the first DC voltage DV1 output by the main power supply circuit 41 into a second intermediate DC voltage MDV2 and outputs the second intermediate DC voltage MDV2 to the second DC/DC converter 64 . The second DC/DC converter 64 converts the second intermediate DC voltage MDV2 output by the first DC/DC converter 52 into a fourth DC voltage DV4 of 3V and outputs the fourth DC voltage DV4 to the engine controller 61 .

The power storage element circuit 65 stores power from the second DC voltage DV2 generated by the sub power supply circuit 42 .

<Image forming unit 70>
The image forming unit 70 is an electrophotographic mechanism that forms a color image on the sheets 3 (see FIG. 1) such as printing paper that are conveyed one by one along the conveying path. The image forming unit 70 includes a scanner unit having a light source for outputting a laser beam, a polygon mirror, and a polygon motor, and a conveying unit having conveying rollers for conveying sheets. A motor is provided to generate the force.

<Operation panel 80>
The operation panel 80 has a power key 81 for turning on/off the power of the image forming apparatus 1 .

FIG. 4 is a block diagram showing details of the power board 40 and the engine board 60. As shown in FIG.

<Main power supply circuit 41>
The main power supply circuit 41 is connected to the first power supply line PL1 and receives alternating voltage from the commercial alternating current power supply AC via the first power supply line PL1. The first power supply line PL1 includes a pair of feeder lines PL11 and PL12. The main power supply circuit 41 has a rectifying/smoothing circuit 411 , a transformer 412 and a control IC 413 .

The rectifying/smoothing circuit 411 has a pair of input terminals 4111 and 4112 . One input terminal 4111 is connected to one feeder line PL11. The other input terminal 4112 is connected to the other feeder line PL12.

The rectifying/smoothing circuit 411 is configured, for example, by bridge-connecting a transformer having both terminals of a primary coil connected to a pair of input terminals 4111 and 4112 and four diodes. It includes a bridge circuit connected to both terminals of the coil, and a capacitor having a pair of electrodes respectively connected to a pair of output terminals of the bridge circuit.

With this configuration, the AC voltage input from the pair of power supply lines PL11 and PL12 of the first power supply line PL1 to the pair of input terminals 4111 and 4112 of the rectifying/smoothing circuit 411 is converted into a DC voltage of a predetermined voltage by the rectifying/smoothing circuit 411. and output from the rectifying/smoothing circuit 411 .

The transformer 412 transforms the DC voltage output from the rectifying/smoothing circuit 411 into a first DC voltage DV1 of 6V or 24V according to control by the control IC 413, and outputs the first DC voltage DV1 to the engine board 60. do.

The control IC 413 controls the transformer 412 to output the first DC voltage DV1 from the transformer 412 and stop the output of the first DC voltage DV1. The control IC 413 turns on/off the output of the first DC voltage DV1 to the engine board 60 by starting/stopping the control of the transformer 412 according to the on/off signal received from the sub-controller 62 . Further, the control IC 413 receives a 6V/24V switching signal from the main controller 51, and operates the transformer 412 so as to switch the output of the first DC voltage DV1 to the engine board 60 according to the received 6V/24V switching signal. Control.

<Sub power supply circuit 42>
The sub-power supply circuit 42 is connected to the second power supply line PL2, and receives AC voltage from the commercial AC power supply AC through the second power supply line PL2. The sub-power supply circuit 42 has a first capacitor 421 , a second capacitor 422 and a rectifying/smoothing circuit 423 .

The first capacitor 421 has a first electrode EP1 and a second electrode EP2. The first electrode EP1 is connected to one power supply line PL21 of the second power supply line PL2 via a connection line CL1. The power supply line PL21 is connected to one end of a commercial AC power supply AC. The second electrode EP2 is connected to the input terminal 4231 of the rectifying/smoothing circuit 423 .

The second capacitor 422 has a third electrode EP3 and a fourth electrode EP4. The third electrode EP3 is connected to the other power supply line PL22 of the second power supply line PL2 via the connection line CL2. The power supply line PL22 is connected to the other end of the commercial AC power supply AC. The fourth electrode EP4 is connected to the input terminal 4232 of the rectifying/smoothing circuit 423 .

The rectifying/smoothing circuit 423 has a pair of input terminals 4231 and 4232 . A second electrode EP2 of the first capacitor 421 is connected to one input terminal 4231 . A fourth electrode EP4 of the second capacitor 422 is connected to the other input terminal 4232 .

The AC power supplied from the commercial AC power supply AC through the second power supply line PL2 has its voltage amplitude suppressed by the impedance of the first capacitor 421 and the second capacitor 422, and is supplied to the pair of input terminals 4231 of the rectifying/smoothing circuit 423. , 4232.

The rectifying/smoothing circuit 423 has the same configuration as the rectifying/smoothing circuit 411 of the main power supply circuit 41 . The rectifying/smoothing circuit 423 is applied to the first capacitor 421 and the second capacitor 422, rectifies and smoothes the AC voltage that is input to the pair of input terminals 4231 and 4232, and converts it into a second DC voltage that is a predetermined sub power supply voltage. Generate voltage DV2. The rectifying/smoothing circuit 423 outputs the second DC voltage DV2 to the sub-controller 62 via the storage element circuit 65 .

<Engine controller 61>
The engine controller 61 is driven in the ON state in which the fourth DC voltage DV4 is supplied from the second DC/DC converter 64 . The engine controller 61 receives a control start signal or a control stop signal from the main controller 51 in the ON state.

Upon receiving the start signal, the engine controller 61 performs initialization such as rewriting registers built into the engine controller 61 to initial values, and starts executing a program for controlling the image forming section 70 . Upon receiving the stop signal, engine controller 61 stops executing the program for controlling image forming section 70 .

<Sub-controller 62>
The sub-controller 62 is driven by a second DC voltage DV2 of 3V generated by the rectifying/smoothing circuit 423 of the sub-power supply circuit 42 and input via the storage element circuit 65 . Since the sub-controller 62 is driven by the second DC voltage DV2 from the sub-power supply circuit 42, it can be driven even when the main power supply circuit 41 is off.

When the sub-controller 62 detects that the power key 81 (see FIG. 3) of the operation panel 80 has been turned on/off, it transmits an on/off signal to the control IC 413 of the main power supply circuit 41 . Upon receiving the main power circuit stop signal from the main controller 51 , the sub-controller 62 transmits an off signal to the control IC 413 of the main power circuit 41 .

<Storage element circuit 65>
The storage element circuit 65 is connected between the sub-power supply circuit 42 and the sub-controller 62 . The storage element circuit 65 is a circuit in which a backup capacitor 651, a resistor 652, and a diode 653 are connected in series.

The backup capacitor 651 has a fifth electrode EP5 and a sixth electrode EP6. The fifth electrode EP5 is connected to the ground GR. A series circuit of a resistor 652 and a diode 653 is connected to the sixth electrode EP6. Specifically, the sixth electrode EP6 is connected to one end 6521 of the resistor 652 . The diode 653 has an anode connected to the output terminal OUT3 of the first DC/DC converter 63 and a cathode connected to the other end 6522 of the resistor 652 .

<First DC/DC converter 63>
The first DC/DC converter 63 has a switch 631 and a conversion circuit 632 . The switch 631 switches between the main power supply circuit 41 and the conversion circuit 632 to close/open according to an on signal/off signal from the main controller 51 . When the switch 631 is closed, the conversion circuit 632 converts the first DC voltage DV1 output from the main power supply circuit 41 into a second intermediate DC voltage MDV2, and converts the second intermediate DC voltage MDV2 to the second DC/DC converter. 64.

When a DC voltage is output from the output terminal OUT3 of the first DC/DC converter 63, the voltage is applied between the fifth electrode EP5 and the sixth electrode EP6 of the backup capacitor 651, and the backup capacitor 651 is charged. .

When the commercial AC power supply AC is connected to the second power supply line PL2 of the power supply board 40, the sub-controller 62 is driven by the second DC voltage DV2 output by the sub-power supply circuit . When the commercial AC power supply AC is not connected to the second power supply line PL2 of the power supply board 40, the sub-controller 62 is driven by the DC voltage stored by the backup capacitor 651 of the storage element circuit 65 and output.

<Sequence at startup>
FIG. 5 is a sequence chart showing processing when the image forming apparatus 1 is started.

When the main power circuit 41 is switched from off to on, for example, when the power key 81 on the operation panel 80 is turned on, the sub power circuit 42 on the power board 40 is turned on (step S101).

When the sub-power supply circuit 42 is turned on, the sub-controller 62 is activated from the off state and turned on, and outputs an on signal to the main power supply circuit 41 (step S102).

When receiving the ON signal from the sub-controller 62, the main power supply circuit 41 outputs the first DC voltage DV1 of 6V to the third DC/DC converter 52 (step S103).

In the controller board 50, the first DC voltage DV1 of 6V is received from the main power supply circuit 41, the third DC/DC converter 52 is turned on (step S104), and the fourth DC/DC converter 53 receives the first intermediate DC voltage MDV1. is turned on (step S105), and the main controller 51 is turned on by the third DC voltage DV3 (step S106).

When the fourth DC/DC converter 53 is turned on, the sub-controller 62 outputs a PGOOD signal, which is a detection signal indicating that the third DC voltage DV3 output to the main controller 51 is equal to or higher than the voltage required to drive the main controller 51. (step S107).

When the sub-controller 62 receives the PGOOD signal from the fourth DC/DC converter 53, the PGOOD signal indicates that the third DC voltage DV3 to be output to the main controller 51 is equal to or higher than the required voltage. to transmit a control start signal (step S108).

When the main controller 51 receives the control start signal from the sub-controller 62 in the ON state, it initializes itself including register initialization, and transmits an ON signal to the first DC/DC converter 63 (step S109). ).

In the engine board 60, when the first DC/DC converter 63 receives the ON signal from the main controller 51, it is turned ON (step S110), and the second DC/DC converter 64 is turned ON by the second intermediate DC voltage MDV2. (Step S111), the engine controller 61 is turned on by the fourth DC voltage DV4 (Step S112).

When the second DC/DC converter 64 is turned on, the main controller 51 outputs a PGOOD signal, which is a detection signal indicating that the fourth DC voltage DV4 output to the engine controller 61 is equal to or higher than the voltage required to drive the engine controller 61. (step S113).

When the main controller 51 receives the PGOOD signal from the second DC/DC converter 64, the PGOOD signal indicates that the fourth DC voltage DV4 to be output to the engine controller 61 is equal to or higher than the required voltage. to transmit a control start signal (step S114). When the engine controller 61 receives a control start signal from the main controller 51 in the ON state, it initializes itself (step S115).

The main controller 51 further transmits a 24V switching signal to the main power supply circuit 41 (step S116). When the main power supply circuit 41 receives the 24V switching signal from the main controller 51, it outputs the first DC voltage DV1 of 24V (step S117). As described above, the process when the image forming apparatus 1 is activated is completed.

<Sequence at end>
FIG. 6 is a sequence chart showing processing when the image forming apparatus 1 ends.

The sub-controller 62 transmits a control stop signal to the main controller when the main power supply circuit 41 shifts from the on state to the off state, for example, when the power key 81 of the operation panel 80 is turned off ( step S201).

When the main controller 51 receives the control stop signal from the sub-controller 62, the main controller 51 executes the off preparation process, and after completing the off preparation process, transmits the control stop signal to the engine controller 61 (step S202).

When the engine controller 61 receives the control stop signal from the main controller 51, the engine controller 61 executes and completes the turn-off preparation process (step S203).

After that, the main controller 51 transmits an OFF signal to the first DC/DC converter 63 (step S204).

In the engine board 60, the first DC/DC converter 63 is turned off upon receiving the off signal from the main controller 51 (step S205), the third DC/DC converter 64 is turned off (step S206), and the engine controller 61 is turned off (step S207).

After the main controller 51 completes its own off-preparation processing and the off-preparation processing of the engine controller 61, the main controller 51 sends a stop signal to the sub-controller 62 to instruct the sub-controller 62 to shift from the on state to the off state of the main power supply circuit 41. is transmitted (step S208). Upon receiving the stop signal from the main controller 51, the sub-controller 62 transmits an off signal to the main power supply circuit 41 (step S209).

The main power supply circuit 41 turns off when it receives an off signal from the sub-controller 62 (step S210). When the main power supply circuit 41 is turned off, in the controller board 50, the third DC/DC converter 52 is turned off (step S211), the fourth DC/DC converter 53 is turned off (step S212), and the main controller 51 is turned off. is turned off (step S213). As described above, the processing when the image forming apparatus 1 ends is completed.

[Modification 1]
As Modified Example 1, an image forming apparatus 1A will be described. In particular, differences between the image forming apparatus 1 and the image forming apparatus 1A will be described.

FIG. 7 is a diagram showing an overview of the configuration of the image forming apparatus 1A. FIG. 7A is a diagram showing an overview of the internal configuration of the image forming apparatus 1A viewed from above. FIG. 7B is a diagram showing an outline of the internal configuration of the image forming apparatus 1A viewed from the left side.

As shown in FIG. 7A, in the image forming apparatus 1A, the engine board 60 is hidden behind the controller board 50 when viewed in a direction parallel to the board surfaces 601 and 501. As shown in FIG. That is, the controller board 50 and the engine board 60 are arranged so that the board surface 501 of the controller board 50 and the board surface 601 of the engine board 60 are included in the same plane. In this case, the controller board 50 and the engine board 60 are connected by a normal harness.

As shown in FIG. 7B, the power supply board 40 and the controller board 50 are arranged on opposite sides with the engine board 60 interposed therebetween.

As shown in FIGS. 7A and 7B, in the image forming apparatus 1A, the power supply board 40 includes a board surface 401 of the power supply board 40, a board surface 501 of the controller board 50, and an engine board 60. The substrate surface 601 is arranged so as to be perpendicular to each other.

According to the above, the engine board 60 is arranged closer to the power supply board 40 than the controller board 50 is.

[Modification 2]
As a modification 2, an image forming apparatus 1B will be described. In particular, differences between the image forming apparatus 1 and the image forming apparatus 1B will be described.

As shown in FIG. 3 , in the image forming apparatus 1 , the main controller 51 of the controller board 50 transmits a stop signal of the main power supply circuit 41 to the sub-controller 62 of the engine board 60 . Therefore, a signal line for transmitting a stop signal for the main power supply circuit 41 is arranged between the controller board 50 and the engine board 60 .

FIG. 8 is a block diagram showing the board configuration of the image forming apparatus 1B. As shown in FIG. 8, in the image forming apparatus 1B, in the engine board 60, the engine controller 61 transmits a stop signal for the main power supply circuit 41 to the sub-controller 62. As shown in FIG.

According to the above, in the image forming apparatus 1B, the main controller 51 does not transmit the stop signal of the main power circuit 41 to the sub-controller 62. A signal line for transmitting a stop signal becomes unnecessary. Therefore, signal lines between the controller board 50 and the engine board 60 can be reduced.

FIG. 9 is a sequence chart showing processing at the end of image forming apparatus 1B.

The sub-controller 62 transmits a control stop signal to the main controller 51 when the main power supply circuit 41 shifts from the on state to the off state, for example, when the power key 81 of the operation panel 80 is turned off ( step S301).

When the main controller 51 receives the control stop signal from the sub-controller 62, the main controller 51 executes the OFF preparation process, and after completing the OFF preparation process, transmits the control stop signal to the engine controller 61 (step S302).

When the engine controller 61 receives the control stop signal from the main controller 51, the engine controller 61 executes and completes the turn-off preparation process (step S303).

After that, the engine controller 61 transmits a stop signal to the sub-controller 62 to instruct the main power supply circuit 41 to shift from the on state to the off state (step S304). Upon receiving the stop signal from the engine controller 61, the sub-controller 62 transmits an off signal to the main power supply circuit 41 (step S305).

The main power supply circuit 41 turns off when it receives an off signal from the sub-controller 62 (step S306).

When the main power supply circuit 41 is turned off, in the engine board 60, the first DC/DC converter 63 is turned off (step S307), the second DC/DC converter 64 is turned off (step S308), and the engine controller 61 is turned off (step S309).

When the main power supply circuit 41 is turned off, the third DC/DC converter 52 is turned off (step S310), the fourth DC/DC converter 53 is turned off (step S311), and the main power supply circuit 41 is turned off. The controller 51 is turned off (step S312). As described above, the processing at the end of the image forming apparatus 1B is completed.

The present invention is not limited to the above-described embodiments, but can be modified in various ways within the scope of the claims, and can be obtained by appropriately combining technical means disclosed in different embodiments. is also included in the technical scope of the present invention.

1, 1A, 1B image forming apparatus 40 power supply board 41 main power supply circuit 42 sub power supply circuit 50 controller board 51 main controller 52 third DC/DC converter 53 fourth DC/DC converter 60 engine board 61 engine controller 62 sub-controller 65 storage element circuit 70 image forming unit 411, 423 rectification smoothing circuit 421 first capacitor 422 second capacitor PL1 first power supply line PL2 second power supply line DV1 first DC voltage DV2 second DC voltage DV3 third DC voltage

Claims (9)

an image forming unit;
A main power supply circuit that converts an AC voltage supplied from a commercial power source through a first power line into a first DC voltage and outputs the first DC voltage; and an AC voltage that is supplied from the commercial power source through a second power line. a power supply board having a sub-power supply circuit that converts to a second DC voltage and outputs the second DC voltage;
a controller board having a main controller driven based on the first DC voltage;
An engine controller driven by the first DC voltage to control the image forming unit, and a sub-controller driven by the second DC voltage to output an on/off signal to a main power supply circuit of the power supply board. and an engine board having
with
The engine board is arranged closer to the power supply board than the controller board,
An image forming apparatus characterized by: The controller board and the engine board are arranged such that their board surfaces are parallel to each other,
The power supply board and the controller board are arranged on opposite sides of each other with the engine board interposed therebetween.
2. The image forming apparatus according to claim 1, wherein: The controller board and the engine board are arranged such that their board surfaces are included in the same plane,
The power supply board and the controller board are arranged on opposite sides of each other with the engine board interposed therebetween.
2. The image forming apparatus according to claim 1, wherein: The sub power supply circuit
a first capacitor connected to one end of the commercial power supply;
a second capacitor connected to the other end of the commercial power supply;
a rectifying and smoothing circuit that rectifies and smoothes the AC voltage applied to the first capacitor and the second capacitor to generate the second DC voltage;
The sub-controller is driven by the second DC voltage generated by the rectifying and smoothing circuit,
4. The image forming apparatus according to claim 1, wherein: The engine board has a power storage element that stores power from the second DC voltage generated by the sub-power supply circuit,
The sub-controller is
driven by the second DC voltage output by the sub power supply circuit in a state where the commercial power supply is connected to the second power supply line;
In a state where the commercial power supply is not connected to the second power supply line, the power storage element is driven by the voltage output.
5. The image forming apparatus according to claim 4, wherein: The controller board is
a DC/DC converter that converts the first DC voltage into a third DC voltage and outputs the third DC voltage to the main controller;
The DC/DC converter is
outputting a detection signal indicating whether or not the third DC voltage is equal to or higher than the voltage required to drive the main controller;
The sub-controller is
outputting an on signal to the main power supply circuit when the main power supply circuit transitions from an off state to an on state;
receiving the detection signal, and instructing the main controller to start control when the detection signal indicates that the third DC voltage is equal to or higher than the required voltage;
6. The image forming apparatus according to claim 4, wherein: The sub-controller is
instructing the main controller to stop control when the main power supply circuit transitions from the on state to the off state;
The main controller is
off-preparation processing is executed in response to the stop instruction from the sub-controller, and after the off-preparation processing is completed, the sub-controller is instructed to shift the main power supply circuit from the on state to the off state. do,
The sub-controller outputs an off signal to the main power supply circuit according to the transition instruction.
6. The image forming apparatus according to claim 4, wherein: The main controller is
instructing the engine controller to stop control in response to the instruction to stop from the sub-controller;
The engine controller
executing an off preparation process for the engine controller in response to the stop instruction from the main controller;
The main controller is
After completion of off-preparation processing for itself and the engine controller, instructing the sub-controller to shift the main power supply circuit from the on state to the off state;
8. The image forming apparatus according to claim 7, wherein: The sub-controller is
instructing the main controller to stop control when the main power supply circuit transitions from the on state to the off state;
The main controller is
instructing the engine controller to stop control in response to the instruction to stop from the sub-controller;
The engine controller
Execution of off-preparation processing for the engine controller in response to the instruction to stop the main controller, and after completion of the off-preparation processing for the engine controller, the sub-controller is switched from the on state to the off state of the main power supply circuit. to instruct the transition to
6. The image forming apparatus according to claim 4, wherein:

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