JP2022003371A - Image forming apparatus - Google Patents

Abstract

To provide means that can detect the occurrence of an abnormality in driving members even if the number of abnormality detection circuits is reduced.SOLUTION: An image forming apparatus has: a first driving member that operates based on a first power input thereto; a second driving member that operates based on the first power or a second power via winding, and when an operation abnormality occurs, outputs an identification signal different from a signal during normal operation; a driving unit that, based on a first driving signal input thereto, supplies the first power to the first driving member to drive the first driving member, and based on a second driving signal input thereto, supplies the first power or the second power to the second driving member to drive the second driving member; and a control unit that outputs the first driving signal and the second driving signal to control the driving unit and receives input of the identification signal. The control unit controls the driving unit to switch between the first power and the second power supplied to the second driving member, and detects an abnormality in the first driving member based on the identification signal.SELECTED DRAWING: Figure 5

Description

The present invention relates to an image forming apparatus that conveys a printing medium and forms an image on the printing medium.

In the conventional image forming apparatus, in order to detect an abnormality of an actuator as a driving member such as a solenoid or an electromagnetic clutch, the current value detected according to each driving signal is detected, and the rotation speed is determined for FAN. Some actuators are provided with one abnormality detection circuit, such as detecting an abnormality by detecting the abnormality (see, for example, Patent Document 1).

Japanese Unexamined Patent Publication No. 2013-41093

However, in the conventional technique, an abnormality detecting circuit for detecting an abnormality of the first driving member (for example, an abnormality in the rotation of the FAN) is provided, and an abnormality of the second driving member (for example, disconnection of the solenoid magnet or the electromagnetic clutch) is provided. If an abnormality detection circuit is not provided to detect, when an abnormality such as a medium transport jam occurs in the printing operation, after confirming the occurrence status, the configuration of the abnormality detection circuit must be confirmed to estimate the defective part. There is a problem that it does not become.
An object of the present invention is to solve such a problem, and an object of the present invention is to be able to detect the occurrence of an abnormality in a driving member even if the number of abnormality detection circuits is reduced.

Therefore, the present invention is based on a first drive member that has a winding and operates on the basis of an input first power and a second power via the first power or the winding. When it operates and an operation abnormality occurs, the second drive member outputs an identification signal different from the signal at the time of normal operation, and the first drive member is based on the input first drive signal. The first electric power is supplied to drive the first driving member, and the first electric power or the second electric power is supplied to the second driving member based on the input second driving signal. It has a drive unit that drives the second drive member, and a control unit that outputs the first drive signal and the second drive signal to control the drive unit and inputs the identification signal. The control unit controls the drive unit to switch between the first electric power and the second electric power supplied to the second drive member, and the first drive member is based on the identification signal. It is characterized by detecting an abnormality.

The present invention in this way has the effect that the occurrence of an abnormality in the driving member can be detected even if the abnormality detection circuit is reduced.

Schematic side sectional view showing the configuration of the image forming apparatus in the embodiment. A block diagram showing a connection configuration of a low-voltage power supply, a cooling fan, and an electromagnetic clutch in an embodiment. A circuit diagram showing a configuration of a connection circuit between a cooling fan and an electromagnetic clutch in an embodiment. Truth table of the connection circuit of the cooling fan and the electromagnetic clutch in the embodiment Flow chart showing the flow of failure detection processing in the embodiment

Hereinafter, examples of the image forming apparatus according to the present invention will be described with reference to the drawings.

FIG. 1 is a schematic side sectional view showing a configuration of an image forming apparatus in an embodiment.

In FIG. 1, the image forming apparatus 100 is, for example, an electrophotographic color printer, which includes a paper feed cassette 102, resist rollers 104, 105, a transport belt 114, and an ID unit 111 (111K, 111Y, 111M, 111C). , LED (Light Emitting Diode) head 112 (112K, 112Y, 112M, 112C), transfer roller 113 (113K, 113Y, 113M, 113C), fuser 116, discharge rollers 119, 120, and cooling FAN 133. have.

The paper cassette 102 houses the print medium P as a medium inside. The print media P stacked and accommodated in the paper cassette 102 are fed out by the rotating hopping roller 103 in the medium transport direction indicated by the arrow A in the figure.
The resist rollers 104 and 105 are arranged downstream of the hopping roller 103 in the medium transport direction, correct the skew of the print medium P unwound by the hopping roller 103, and deliver the print medium P to the transport belt 114 at a predetermined timing. It is a thing.

The roller shaft of the registration roller 105 is provided with an electromagnetic clutch 121 (see FIG. 2) having a built-in coil. When power is supplied (ON) to the electromagnetic clutch 121, the registration roller 105 and the electromagnetic clutch 121 are engaged with each other, which will be described later. The power from the motor 135 (see FIG. 2) can be transmitted to the resist roller 105.
Further, when the power supply to the electromagnetic clutch 121 is stopped (OFF), the engagement between the resist roller 105 and the electromagnetic clutch 121 is released, and the resist roller 105 is stopped. By utilizing this operation, the resist roller 105 is stopped during the transfer of the print medium P, and the tip of the print medium P is brought into contact with the resist roller 105 for a certain period of time, so that the skew of the print medium P can be corrected. It has a structure.

The conveyor belt 114 is an endless belt rotatably stretched on the drive roller 115, and conveys the print medium P conveyed by the resist roller 105.

The ID unit 111 (111K, 111Y, 111M, 111C) is arranged so as to face the transfer belt 114, and also faces the ID unit 111 (111K, 111Y, 111M, 111C) via the transfer belt 114. , Transfer rollers 113 (113K, 113Y, 113M, 113C) are arranged.

The ID unit 111 (111K, 111Y, 111M, 111C) is an image forming unit that forms a toner image as a developer image on a photosensitive drum as an image carrier. ID units 111K, 111Y, 111M, 111C are arranged in order from the upstream side in the medium transport direction, and the ID units 111K, 111Y, 111M, 111C are K (black), Y (yellow), M (magenta), C ( It is an electronic LED printing mechanism that forms a toner image with toner as a developer for each color of cyan).

The ID unit 111 (111K, 111Y, 111M, 111C) is provided with a removable toner cartridge 122 (122K, 122Y, 122M, 122C) for accommodating toner inside.
Further, the ID unit 111 (111K, 111Y, 111M, 111C) is provided with an LED head 112 (112K, 112Y, 112M, 112C).

The LED head 112 (112K, 112Y, 112M, 112C) is an exposure means for exposing the surface of a charged photosensitive drum to form an electrostatic latent image. Charged toner is attached to the electrostatic latent image formed on the surface of the photosensitive drum, and a toner image is formed.
The transfer roller 113 (113K, 113Y, 113M, 113C) transfers the toner image of each color formed on the photosensitive drum of the ID unit 111 (111K, 111Y, 111M, 111C) to the print medium P conveyed by the transfer belt 114. It is to be transferred.

The fuser 116 is a fixing means for fixing the toner by heating and fusing the toner transferred to the printing medium P conveyed by the conveying belt 114. The fuser 116 includes a fixing roller 117 having a planar heater and a backup roller 118, and the fixing roller 117 is heated to a fixable temperature by the electric power applied to the planar heater.
The discharge rollers 119 and 120 are discharge means for discharging the print medium P on which the toner is fixed to the outside of the apparatus.

The cooling FAN 133 is a blower that cools a low-voltage power supply 132 that supplies electric power to a heat source, an actuator, or the like. The low-voltage power supply 132 supplies electric power to, for example, the fuser 116, the electromagnetic clutch 121 described later, the transfer motor 135, the cooling FAN 133, and the like.
The image forming apparatus 100 configured in this way includes a control unit having a CPU (Central Processing Unit) and other storage means such as a memory, and is imaged by the control unit based on the control program (software) stored in the storage means. The operation of the entire forming device 100 is controlled.

Further, the image forming apparatus 100 includes an operator panel having a display unit such as a display and an operation input unit such as a key or a touch panel, and is capable of displaying various information and accepting a user's operation.
FIG. 2 is a block diagram showing a connection configuration of a low voltage power supply, a cooling fan, and an electromagnetic clutch in an embodiment.

In FIG. 2, the low-voltage power supply 132 is a power supply unit that supplies the power of the entire image forming apparatus 100 shown in FIG. The low voltage power supply 132 is a switching power supply, and an AC power 131 which is a commercial power supply is connected to the low voltage power supply 132.

The low-voltage power supply 132 is a transfer motor 135 via a control unit 134 by an AC / DC conversion circuit 137 that generates a drive voltage of a 24 V motor or the like including the electric power input to the heat source of the fuser 116, that is, the planar heater. The electric power of the electromagnetic clutch 121 and the cooling FAN 133 is supplied, and the electric power is also supplied to the control unit 134 by the AC / DC conversion circuit 136 that generates a logic voltage such as a 5V CPU 138.

The electromagnetic clutch 121 as the first driving member is an actuator having a coil (winding) inside or the like and operating based on the input first electric power (24V).
As will be described later, the cooling FAN 133 as the second driving member operates based on the first electric power (24V) or the second electric power via the coil of the electromagnetic clutch 121, and is normal when an operation abnormality occurs. It is an actuator that outputs an identification signal (FAN error signal) different from the signal during operation.

The low-voltage power supply 132 can be cooled by the cooling FAN 133 so as not to damage or deteriorate the parts used for the low-voltage power supply 132 due to heat generated by the switching operation for power conversion during the printing operation in which the power load is the heaviest in the operation mode of the image forming apparatus. It is configured in.
Further, the cooling FAN 133 is a DC drive FAN whose rotation speed is reduced by lowering the applied drive voltage, and is a circuit as an abnormality detecting means for generating an error signal (FAN error signal) by detecting the presence or absence of rotation. Is built-in.

The error signal generated by the cooling FAN 133 is connected to the input port of the CPU 138 mounted on the control unit 134, and the control unit 134 can detect an abnormality of the cooling FAN 133 by monitoring the error signal when the cooling FAN 133 is driven. It has become like.
Further, when the printing operation is completed, the power load on the low voltage power supply 132 decreases, and the low voltage power supply 132 also suppresses heat generation due to the switching operation for power conversion, so that the drive voltage applied to the cooling FAN 133 can be reduced. A drive circuit is configured in the above, and the drive noise of the cooling FAN 133 is reduced by reducing the rotation speed of the cooling FAN 133.

The control unit 134 has an input / output port, and as shown in FIG. 3, outputs an electromagnetic clutch ON1 signal from the output port 301, outputs an electromagnetic clutch ON2 signal from the output port 302, and outputs a FANON signal from the output port 303. It outputs and controls the drive unit 200, and also inputs an error signal (FAN error signal) from the cooling FAN 133 through the input port 304.

FIG. 3 is a circuit diagram showing a configuration of a connection circuit of a cooling fan and an electromagnetic clutch in an embodiment.
In FIG. 3, the drive unit 200 supplies the electromagnetic clutch 121 with the first power (24V) based on the electromagnetic clutch ON1 signal and the electromagnetic clutch ON2 signal as the input first drive signals to provide the electromagnetic clutch 121. The cooling FAN 133 is supplied with the first power (24V) or the second power via the coil of the electromagnetic clutch 121 based on the WANON signal as the input second drive signal and the electromagnetic clutch ON2 signal. It is a drive circuit for driving the cooling FAN 133, and is composed of a first drive unit 210 and a second drive unit 220.

The first drive unit 210 is a drive circuit that supplies the first electric power (24V) to the electromagnetic clutch 121 based on the input electromagnetic clutch ON1 signal and electromagnetic clutch ON2 signal to drive the electromagnetic clutch 121.
The first drive unit 210 includes a FET (Field Effect Transistor) 307, a transistor 308, and a transistor 310.

The second drive unit 220 uses the input FANON signal and the electromagnetic clutch ON2 signal to connect the cooling FAN 133 in series with the electromagnetic clutch 121 to the first electric power or the second electric power via the coil of the electromagnetic clutch 121. It is a drive circuit that supplies and drives the cooling FAN 133.
The second drive unit 220 includes a transistor 306, a transistor 309, a FET 307, a transistor 308, and a transistor 310.

The output port 301 (output port of the CPU 138 shown in FIG. 2) is connected to the NPN transistor 310 via a resistor, and is a PNP switch for supplying 24V, which is a power source for driving the electromagnetic clutch 121, to the electromagnetic clutch 121. It is connected to the transistor 308.

The drive signal generated by the output port 301 is output as an electromagnetic clutch ON1 signal, which is a signal for driving and controlling the electromagnetic clutch 121.

Further, the output port 302 (the output port of the CPU 138 shown in FIG. 2) is connected to the FET 307 via a resistor, and is connected as a ground side switch of the electromagnetic clutch 121 so that the drive of the electromagnetic clutch 121 can be controlled by the power of the drive power supply 24V. ing.
The drive signal generated by the output port 302 is output as an electromagnetic clutch ON2 signal, which is a signal for driving the electromagnetic clutch 121.

That is, when both the transistor 308 and the FET 307 are turned on, 24V is supplied to the electromagnetic clutch 121, and the electromagnetic clutch 121 is in the drive (ON) state.
The output port 303 (output port of the CPU 138 shown in FIG. 2) is connected to the NPN transistor 306 via a resistor, and further connected to the PNP transistor 309 which is a switch for supplying 24V, which is a power source for driving the FAN 133, to the FAN 133. Has been done.

Further, a freewheeling diode 311 is connected between the emitter and the collector of the transistor 309 so that the reverse bias is not applied to the transistor 309 due to the counter electromotive force generated when the FAN 133 is stopped.
A cooling fan 133 is connected to the collector terminal of the transistor 309, and the fanON signal generated at the output port 303 is configured to be able to supply a drive voltage of 24V to the cooling fan 133 using the transistor 309 as a switch.

The cooling FAN 133 is a DC (Direct Current) fan capable of rotating at a variable rotation speed according to a supplied drive voltage, and outputs a FAN error signal.
The FAN error signal as an identification signal is an open collector output, and outputs "0", which is 0V, to indicate that the rotation is in progress when the rotation speed reaches a certain level, and outputs an open output when the rotation speed is stopped.

Further, the FAN error signal is connected to the input port 304 (the input port of the CPU 138 shown in FIG. 2), and the FAN error signal output by the cooling FAN 133 indicates that the cooling FAN 133 is stopped even though the drive voltage is applied to the cooling FAN 133. If the output remains open, a 5V pull-up resistor keeps inputting "1" indicating that the input port 304 is stopped, and the CPU 138 shown in FIG. 2 is connected so as to be able to detect a defect in the cooling FAN 133. There is.

That is, the FAN error signal is an identification signal different from the signal during normal operation.

In the drive circuit of the cooling FAN 133 and the electromagnetic clutch 121, the anode terminal of the diode 305 is connected to the drain terminal of the FET 307 and the ground side of the electromagnetic clutch 121, and the cathode side of the diode 305 is connected to the drive voltage supply terminal of the cooling FAN 133.

The operation of the above-mentioned configuration will be described.

First, the printing operation performed by the image forming apparatus will be described with reference to FIGS. 1 and 2. The printing operation is performed based on a control program stored in a storage means such as a memory by the control unit 134 provided in the image forming apparatus 100.

The control unit 134 of the image forming apparatus 100 receives print data as a print command from an external device via a communication line and an I / F control unit. The control unit 134 that has received the print data separates the print media P contained in the paper feed cassette 102 one by one by the hopping roller 103, feeds them, and conveys them to the resist rollers 104 and 105 to further form an image. The electromagnetic clutch 121 and the transfer motor 135 are controlled according to the timing, and are transferred to the transfer belt 114 and the ID unit 111 (111K, 111Y, 111M, 111C) by the resist roller 105.

At this time, the control unit 134 controls the ID unit 111 (111K, 111Y, 111M, 111C) and the transport belt 114 to form a toner image.

First, the control unit 134 rotates the photosensitive drum of the ID unit 111K and uniformly charges the surface of the photosensitive drum with a charging roller. The control unit 134 was selectively exposed to the surface of the charged photosensitive drum by the LED head 112K according to the print data to form an electrostatic latent image, and then formed on the surface of the photosensitive drum by the developing roller. Toner is supplied to the electrostatic latent image to develop it.

The control unit 134 controls the transfer voltage and the like of the transfer roller 113K to transfer the toner image developed on the surface of the photosensitive drum to the print medium P which is conveyed in the medium transfer direction indicated by the arrow A in FIG.
After the toner image is transferred to the print medium P, the toner remaining on the surface of the photosensitive drum is scraped off by the cleaning blade to clean the surface of the photosensitive drum, and then the photosensitive drum is subjected to the next charging by the charging roller. Toner.

The print medium P on which the black toner image is transferred by the ID unit 111K, the transfer belt 114, and the transfer roller 113K is conveyed in the medium transfer direction, and the ID unit 111Y, the ID unit 111M, and the ID unit 111M perform the same development process as the ID unit 111K. The ID unit 111C, the transfer belt 114, and the transfer rollers 113Y, 113M, 113C transfer the toner images of each color of yellow, magenta, and cyan, and after all the toner images necessary for image formation are transferred, the transfer belt. It is conveyed from 114 to the fuser 116.

The control unit 134 heats the printing medium P with the heater of the fixing device 116 turned on, and the print medium P conveyed to the fixing device 116 is thermocompression bonded at the nip portion between the fixing roller 117 and the backup roller 118, and is placed on the printing medium P. Toner is fixed.
After that, the control unit 134 rotates the discharge rollers 119 and 120 to transport the print medium P in the medium transport direction, discharges the print medium P to the outside of the apparatus, and ends the main printing operation.

The control unit 134 controls the cooling FAN 133 according to each operation mode during the printing operation (first operation mode), the print command standby (second operation mode), and the stop time (third operation mode). Control.
FIG. 4 is a truth table of the connection circuit of the cooling FAN and the electromagnetic clutch in the embodiment, and is a truth table in each operation mode of the first operation mode, the second operation mode, and the third operation mode. The truth table shown in FIG. 4 will be described below with reference to FIGS. 1, 2, and 3.

First, the printing operation (printing operation), which is the first operation mode, will be described.

At the time of printing, it is necessary to turn on / off the drive of each of the cooling FAN 133 and the electromagnetic clutch 121.

For example, in a state where the control unit 134 does not print even one print medium P after the power is turned on to the image forming apparatus 100, the low voltage power supply 132 is in a sufficiently cold state, so that a small amount of printing can be performed. However, it is not necessary to drive the cooling FAN 133, and the printing operation is performed with the cooling FAN 133 stopped (OFF) not only from the viewpoint of noise but also from the viewpoint of power saving.

At this time, the control unit 134 drives the transistor 308 by turning on the electromagnetic clutch ON2 signal, turning on the FET 307, turning off the FANON signal, turning off the transistor 309, and turning on / off the electromagnetic clutch ON2 signal. Then, ON / OFF of the drive of the electromagnetic clutch 121 can be controlled while the cooling FAN 133 is stopped.

Further, the control unit 134 continuously performs the printing operation, and when the low voltage power supply 132 needs to be exhausted, the control unit 134 turns on the electromagnetic clutch ON2 signal and turns on the FANON signal with the FET 307 turned on. The transistor 309 is turned on, and the cooling FAN 133 can be individually driven at full speed (full speed drive).

Next, the standby time, which is the second operation mode, will be described.

During standby, the image forming apparatus 100 is in a state of waiting for an activation command for printing operation, and is not performing printing operation, so that low noise and low power consumption are required.
However, immediately after the printing operation, the low-voltage power supply 132 is in a state of storing heat that was operating in anticipation of the cooling effect of the cooling FAN 133, so that the cooling FAN 133 cannot be stopped suddenly.

Therefore, in order to achieve both cooling and low noise, it is necessary to drive the cooling FAN 133 (low speed drive) at a low speed lower than the full speed to sufficiently cool the low voltage power supply 132.
Here, the low-speed drive is a drive that rotates the cooling FAN 133 at a lower speed than the full-speed drive, for example, a drive that rotates the cooling FAN 133 at a rotation speed that is half of the rotation speed per predetermined time by the full-speed drive.

When driving the cooling FAN 133 during standby at a low speed (low speed drive), the control unit 134 turns on the transistor 308 by turning on the electromagnetic clutch ON1 signal, turns off the FANON signal, and turns off the transistor 309. , The FET 307 is turned off by turning off the electromagnetic clutch ON2 signal.

In this case, power is supplied from the 24V power supply to the cooling FAN 133 via the transistor 308, the electromagnetic clutch 121, and the diode 305.
At this time, the drive current of the cooling FAN 133 flows in the same path, and the drive voltage of the cooling FAN 133 drops due to the winding resistance of the coil built in the electromagnetic clutch 121.

For example, when the drive voltage of the cooling FAN 133 is 24 V and the drive current is 100 mA, and the winding resistance of the electromagnetic clutch 121 is 100 Ω, the drive voltage of the cooling FAN 133 in the state of each signal in the standby state is It is calculated as 24V- (100mA x 100Ω) = 14V.

However, strictly speaking, as the drive voltage of the cooling FAN 133 decreases, the drive current decreases slightly, so that the drive voltage increases slightly with respect to 14 V. When using a FAN whose rotation speed is specified by the drive voltage, in a circuit that realizes low-speed rotation by using a coil, which is a resistor as described above, like the limiting resistance of the drive power supply, the degree of decrease in the drive current of the FAN And there is a high possibility that the rotation speed will be uneven due to the variation in the resistance value of the coil.

Therefore, it is necessary to pay attention to the regulation of the rotation speed in the case of the usage method in which the rotation speed is strictly required even during low-speed driving.

Further, in this state, a current of about 100 mA is also applied to the electromagnetic clutch 121. Only (24V-14V) x 100mA = 1.4W is supplied to 24V x 240mA = 5.76W when the power supply voltage of 24V is expected as normal operation, but the electromagnetic clutch 121 is turned on or only during printing. Since it is an actuator that can be turned off, there is no effect on operation.

Next, a third operation mode, that is, when stopped, will be described.

The third operation mode is a stop state in which the cooling FAN 133 and the electromagnetic clutch 121 are required to be completely turned off by turning off all the outputs of the electromagnetic clutch ON1 signal, the WANON signal, and the electromagnetic clutch ON2 signal. The third operation mode is an operation mode for achieving lower power consumption than the first operation mode and the second operation mode described above, for example, when the second operation mode continues for a predetermined time. It is a power saving mode to shift.

The control unit 134 can completely turn off the cooling FAN 133 and the electromagnetic clutch 121 by turning off all the outputs of the electromagnetic clutch ON1 signal, the fanON signal, and the electromagnetic clutch ON2 signal.

Although it is a combination that is not used, 24V is supplied to both terminals of the electromagnetic clutch 121 by the diode 305 even if the electromagnetic clutch ON2 signal is set to OFF while the electromagnetic clutch ON1 signal is ON and the FANON signal is ON. Since the drive current of the electromagnetic clutch 121 is not generated, the electromagnetic clutch continues to be turned off and the cooling FAN 133 is driven at full speed.

Further, when the electromagnetic clutch ON1 signal is turned off and the FANON signal is turned off, the electromagnetic clutch 121 and the cooling FAN 133 are used with the transistor 308 and the transistor 309 regardless of whether the electromagnetic clutch ON2 signal is set to ON or OFF. Since the supply of 24V is cut off, the electromagnetic clutch 121 and the cooling FAN 133 continue to be turned off.

Next, the failure detection process for detecting the failure (abnormality) of the electromagnetic clutch or the cooling FAN performed by the image forming apparatus is performed according to the step represented by S in the flowchart showing the flow of the failure detection process in the embodiment of FIG. This will be described with reference to FIG.

The failure detection process is performed at a predetermined timing. For example, when the image forming apparatus 100 is turned on or the printing operation is completed, the user detects the failure on the menu screen displayed on the operator panel. It is performed when an operation to the effect is accepted.

S1: Whether or not the control unit 134 of the image forming apparatus 100 can start the failure determination, that is, whether or not the error determination for detecting the failure of the mounted component can be started at an arbitrary timing such as abnormal stop or completion of printing operation. If it is confirmed that the failure determination can be started, the process shifts to S2, and if the failure determination cannot be started, this confirmation is continued.

S2: The control unit 134 sets the output signal for full-speed drive for the cooling FAN 133 to rotate at full speed. The control unit 134 sets the FanON signal to ON and the electromagnetic clutch ON2 signal to ON. The electromagnetic clutch ON1 signal may be ON or OFF. Further, since the fanon signal is detected at the rotation speed, it is desirable to wait until the rotation speed becomes constant before detecting the fanon signal.

S3: The control unit 134 confirms the FAN error signal, and if "0" is detected, determines that the cooling FAN 133 is normally rotating, and shifts the process to S6. On the other hand, when the control unit 134 detects that the FAN error signal is "1", the cooling FAN 133 is not rotating or is in a state where sufficient rotation is not obtained, so that the process shifts to S4.

S4: The control unit 134 detects that the cooling FAN 133 is defective.

S5: The control unit 134 displays on the operator panel that the cooling FAN 133 has failed, and ends this process. By displaying on the operator panel that the cooling FAN 133 is out of order, it is possible to notify the user that maintenance measures are required.

S6: In S3, when the FAN error signal is "0" and no abnormality is found in the cooling FAN 133 during full-speed rotation drive, the control unit 134 sets the low-speed drive for performing the low-speed rotation of the cooling FAN 133.

The control unit 134 switches to the setting of turning off the FanON signal, turning off the electromagnetic clutch ON2 signal, and turning on the electromagnetic clutch ON1 signal.

That is, the control unit 134 controls the drive unit 200 to switch the first electric power (24V) supplied to the cooling FAN 133 to the second electric power via the coil of the electromagnetic clutch 121. More specifically, the control unit 134 controls the second drive unit 220 and supplies the second electric power lower than the first electric power (24V) to the cooling FAN 133.

S7: The control unit 134 confirms the FAN error signal, and if "0" is detected, determines that the electromagnetic clutch 121 is also operating normally, and shifts the process to S10. On the other hand, when the control unit 134 detects that the FAN error signal is "1", it determines that the power is not supplied to the cooling FAN 133, and shifts the process to S8.

S8: The control unit 134 detects that the coil of the electromagnetic clutch 121 is defective based on the FAN error signal.

S9: The control unit 134 displays on the operator panel that the electromagnetic clutch 121 has failed, and ends this process. By displaying on the operator panel that the electromagnetic clutch 121 is out of order, it is possible to notify the user that maintenance measures are required.

S10: The control unit 134 determines that the cooling FAN 133 and the electromagnetic clutch 121 are operating normally, and terminates this process as "no failure".

In this way, the control unit 134 controls the drive unit 200 to switch the first electric power (24V) supplied to the cooling FAN 133 to the second electric power via the coil of the electromagnetic clutch 121, and is based on the FAN error signal. It is detected that the coil of the electromagnetic clutch 121 is defective.

More specifically, the control unit 134 does not detect the FAN error signal when the first electric power (24V) is supplied to the cooling FAN 133, and the second electric power via the coil of the electromagnetic clutch 121 is applied to the cooling FAN 133. When a FAN error signal is detected when the power is supplied, an abnormality in the coil of the electromagnetic clutch 121 is detected.

In this embodiment, there is an effect that the disconnection state of the coil can be detected by the error detection function of the cooling FAN 133 without mounting the solenoid magnet or the dedicated circuit for detecting the disconnection of the electromagnetic clutch 121.

Further, by using the winding resistance of the electromagnetic clutch 121 to reduce the drive voltage of the cooling FAN 133 as a DC FAN to reduce the rotation speed, it becomes possible to perform low-speed rotation drive, which is dedicated to low-speed rotation. Since it is not necessary to mount a circuit, the control board can be downsized.

In this embodiment, the example using the electromagnetic clutch 121 has been described, but it is a form using a solenoid magnet (for example, a solenoid magnet for switching the paper transport path) composed of a coil which is a winding. However, the same effect can be obtained.

As described above, in the present embodiment, the effect that the occurrence of an abnormality in the driving member can be detected even if the abnormality detection circuit is reduced can be obtained.

In this embodiment, the image forming apparatus has been described as a printer, but the present invention is not limited to this, and may be an OA apparatus such as a copying machine, a facsimile machine, or a multifunction device (MFP) equipped with a cooling FAN and an electromagnetic clutch. Is also good.

100 Image forming apparatus 102 Paper cassette 104, 105 Resist roller 111 (111K, 111Y, 111M, 111C) ID unit 112 (112K, 112Y, 112M, 112C) LED head 113 (113K, 113Y, 113M, 113C) Transfer roller 116 Fuser 119, 120 Discharge roller 132 Low voltage power supply 133 Cooling FAN
134 Control unit 135 Conveyor motor 136, 137 AC / DC conversion circuit 138 CPU
200 Drive unit 210 First drive unit 220 Second drive unit 301 Output port (electromagnetic clutch ON1 signal)
302 output port (electromagnetic clutch ON2 signal)
303 Output port (FANON signal)
304 Input port (FAN error signal)

Claims (6)

A first drive member that has windings and operates on the basis of the input first power.
A second drive member that operates based on the first electric power or the second electric power that has passed through the winding, and outputs an identification signal different from the signal at the time of normal operation when an operation abnormality occurs.
The first electric power is supplied to the first drive member based on the input first drive signal to drive the first drive member, and the first drive member is driven based on the input second drive signal. A drive unit that supplies the first electric power or the second electric power to the second drive member to drive the second drive member, and
A control unit that outputs the first drive signal and the second drive signal to control the drive unit and inputs the identification signal.
Have,
The control unit switches between the first electric power and the second electric power that control the drive unit and supply the second drive member, and the abnormality of the first drive member is based on the identification signal. An image forming apparatus characterized by detecting. In the image forming apparatus according to claim 1,
The control unit does not detect the identification signal when the first electric power is supplied to the second drive member, and the identification signal is obtained when the second electric power is supplied to the second drive member. An image forming apparatus, characterized in that, when the above is detected, an abnormality in the winding of the first driving member is detected. In the image forming apparatus according to claim 2,
The drive unit
A first drive unit that supplies the first electric power to the first drive member based on the input first drive signal and drives the first drive member.
Based on the input second drive signal, the first electric power or the second electric power is supplied to the second drive member connected in series with the first drive member, and the second drive is performed. A second drive unit that drives the member,
Have,
The control unit is an image forming apparatus that controls the second driving unit and supplies the second electric power lower than the first electric power to the second driving member. In the image forming apparatus according to claim 2 or 3.
The image forming apparatus, characterized in that, when the control unit detects an abnormality in the winding of the first drive member, the control unit displays on the display unit that the first drive member has failed. The image forming apparatus according to any one of claims 1 to 4.
The second driving member is an image forming apparatus characterized by being a cooling fan. The image forming apparatus according to any one of claims 1 to 5.
The image forming apparatus, wherein the first driving member is an electromagnetic clutch provided on a transport roller.

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