JP6711663B2 - Image forming device - Google Patents

Description

The present invention relates to an image forming apparatus such as an electrophotographic type and an electrostatic recording type.

In an image forming apparatus in which an electrostatic latent image formed on a photoconductor by laser beam light is developed with toner to form a toner image, the formed toner image is transferred to a sheet, and heat-fixed, a medium such as a sheet Characteristic information such as thickness and surface property is important as a control parameter. By using the characteristic information of the medium, it is possible to realize the fixing temperature and the conveying speed that are optimum for the paper. It is generally known that the characteristic information of a sheet is set by a user's operation from an operation unit provided in the image forming apparatus or a driver screen. However, in recent years, a configuration has been proposed in which a sensor for detecting the characteristics of the medium is provided inside the image forming apparatus, which improves convenience by not requiring user operation.

When a different medium is detected while performing an image forming operation with a control parameter suitable for a predetermined medium in an image forming apparatus equipped with a sensor for detecting the characteristics of the medium (hereinafter referred to as a medium sensor) Control is disclosed. For example, a media sensor that detects the characteristics of the paper is arranged on the transport path, and the media is detected for a plurality of papers that are continuously fed (for example, see Patent Document 1). Then, when the characteristics of the already output paper and the characteristics of the newly detected paper are different, the print job is stopped.

JP, 2010-211062, A

However, in order to detect the media with the media sensor arranged on the transport path, it is necessary to feed the paper and transport the paper to the position on the transport path where the media sensor is arranged. When it is determined that the detection result of the media sensor does not match the currently operating control parameter, it is necessary to stop the sheet conveying operation and the image forming operation at the timing of the determination. Therefore, in order for the user to restart the subsequent print job, it is necessary to confirm the paper type of the paper feed cassette, change the paper type setting, and further remove the paper stopped on the transport path. is there.

The present invention has been made under such circumstances, and an object of the present invention is to improve usability even when the set paper type does not match the paper type stored in the storage unit.

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

(1) Paper feeding means for feeding the recording medium stacked in the paper feeding portion, detection means for detecting the type of recording medium fed by the paper feeding means, and manually setting the type of recording medium Printing is performed by one of a setting unit, a first mode that controls the printing operation based on the type of recording medium set by the setting unit, and a second mode that controls the printing operation based on the detection result of the detection unit. and a control means for controlling the operation, and a storage means for storing information about the type of the detected recording medium past by the detecting means, the control means, initiate the printing operation in the first mode If the type of the recording medium set by the setting unit does not match the type of the recording medium determined based on the information about the type of the recording medium stored in the storage unit, The sheet feeding means is controlled not to start feeding the recording medium, and when the set type of the recording medium matches the determined type of the recording medium, the printing operation is started and the sheet feeding means is started. An image forming method in which a recording medium is started to be fed from the paper feeding unit by the detection unit, the recording medium fed from the paper feeding unit is detected by the detection unit, and the detection result is stored in the storage unit. apparatus.
(2) Paper feeding means for feeding the recording medium stacked in the paper feeding portion, detection means for detecting the type of recording medium fed by the paper feeding means, and manually setting the type of recording medium Printing is performed by one of a setting unit, a first mode that controls the printing operation based on the type of recording medium set by the setting unit, and a second mode that controls the printing operation based on the detection result of the detection unit. A control unit that controls the operation; and a storage unit that stores information related to the type of the recording medium detected by the detection unit in the past, and the control unit starts the printing operation in the first mode. If the type of the recording medium set by the setting unit does not match the type of the recording medium determined based on the information about the type of the recording medium stored in the storage unit, When the storage unit does not store the information regarding the type of the recording medium, the sheet feeding unit controls the sheet feeding so as not to start feeding the recording medium, and prints according to the type of the recording medium set by the setting unit. An image forming apparatus characterized by starting operation.

According to the present invention, usability can be improved even when the set paper type does not match the paper type stored in the storage unit.

Sectional view of an image forming apparatus according to an embodiment Block diagram of an image forming apparatus according to an embodiment Sectional view of a fixing device according to an embodiment Explanatory drawing of the media sensor of the embodiment Explanatory diagram of the amount of reflected light according to the paper type of the embodiment Explanatory drawing of the automatic detection mode and instruction mode of the embodiment Flowchart showing print control according to the embodiment The figure which shows the operation part of embodiment

[Embodiment]
<Image forming device>
FIG. 1 is a sectional view of an image forming apparatus 100 according to the embodiment, and FIG. 2 is a block diagram showing a configuration of the present embodiment. A basic configuration will be described with reference to FIGS. 1 and 2. In FIG. 2, the CPU 10, the ROM 11, the RAM 12, and the storage unit 15 which is a storage unit constitute a control unit. An instruction to start a print operation (hereinafter referred to as an operation start instruction) is input to the CPU 10 from the operation unit 13 which is a setting unit. The CPU 10 can drive and control the sheet feeding motor 150 according to an operation start instruction input from the operation unit 13 to feed and convey the sheet. Further, the CPU 10 detects the position of the paper inside the image forming apparatus 100 by monitoring the paper feed pickup sensor 152 and the like.

Further, the CPU 10 controls the image forming unit 17. The image forming unit 17 controls the high voltage application and drive of the cartridges 120a, 120b, 120c, 120d of FIG. Here, the subscripts a, b, c, and d of the symbols represent colors, for example, a is yellow (Y), b is magenta (M), c is cyan (C), and d is black ( K). Hereinafter, the subscripts a to d will be omitted unless a specific color is described. The image forming unit 17 can control the high voltage and drive of the intermediate transfer belt 130, the primary transfer unit 123, the secondary transfer unit 140, and the like, and the laser scanner 122. The ROM 11 stores an image forming procedure and a procedure of a flowchart described later. The media sensor 14 constituting the detection means can detect the material (for example, thickness) of the paper being conveyed on the conveying path, and can output the information regarding the kind of the paper to the CPU 10 described later. Details of the media sensor 14 will be described later.

Next, a basic image forming operation will be described with reference to FIGS. When the operation start instruction is received from the operation unit 13 or the like, the CPU 10 starts the paper feeding operation from the paper feeding cassette 220, which is the paper feeding unit on which the recording mediums are stacked. The paper feed motor 150, which is the drive source of the paper feed pickup roller 151 that is the paper feed means, is driven to rotate the paper feed pickup roller 151, and the paper in the paper feed cassette 220 is fed and conveyed one by one. .. At this time, the CPU 10 uses the paper feed pickup sensor 152 to monitor whether or not the paper feed operation has been performed normally.

When the paper picked up by the paper feed pickup roller 151 and conveyed by the conveyance roller 154 is conveyed to the position of the media sensor 14, the CPU 10 detects the material (thickness, etc.) of the paper by the media sensor 14. At this time, depending on the configuration of the media sensor 14, the paper may be temporarily stopped at the position of the media sensor 14 or the transport speed may be reduced in order to improve the reading accuracy. In the present embodiment, it is not necessary to temporarily stop the conveyance of the paper or reduce the conveyance speed when the detection by the media sensor 14 is performed. The CPU 10 reflects the information of the sheet detected by the media sensor 14 on the image forming condition in the image forming process, for example, the fixing temperature in the fixing process by the fixing device 170. Note that, as another image forming condition, for example, it is conceivable to change the paper conveyance speed to a conveyance speed corresponding to the information detected by the media sensor 14 and continue the paper conveyance. For example, when it is determined from the detection result of the media sensor 14 that the paper being conveyed is thick paper, the conveyance speed of the thick paper is half the conveyance speed The conveyance speed is changed, such as changing to (1/2 speed). In the present embodiment, as an example, the sheet conveyance speed is kept constant and is not changed, and the detection result of the media sensor 14 is reflected in the fixing temperature of the fixing device 170.

The CPU 10 causes the cartridge 120 to start an image forming operation in time for the sheet to arrive at the secondary transfer unit 140. The cartridge 120 is mounted on the main body of the image forming apparatus 100 and has a removable structure. After the surface of the photosensitive drum 121 is charged by the charging roller 124, a latent image is formed on the photosensitive drum 121 by the laser light emitted from the laser scanner 122. The latent image formed on the photosensitive drum 121 is developed with toner in the developing device 125, and a toner image is formed on the photosensitive drum 121. The toner image formed on the photosensitive drum 121 is transferred to the intermediate transfer belt 130 by the primary transfer portion 123 to which a transfer voltage is applied. The toner image transferred onto the intermediate transfer belt 130 is moved to the secondary transfer section 140 along with the movement of the intermediate transfer belt 130.

The CPU 10 detects the position of the sheet conveyed by the conveyance roller 155 by monitoring the pre-registration conveyance sensor 160. The CPU 10 considers the timing when the leading edge of the sheet reaches the pre-registration conveyance sensor 160, so that the leading edge of the sheet matches the leading edge of the toner image on the intermediate transfer belt 130 at the secondary transfer unit 140. Control the transport of. For example, when it is determined that the paper arrives earlier than the specified timing based on the detection result of the pre-registration transport sensor 160, the CPU 10 stops the paper at the position of the pre-registration transport roller 161 for a predetermined time. , Re-start the transport again.

By applying a transfer voltage to the secondary transfer section 140, the toner image is transferred to the sheet that has reached the secondary transfer section 140. The sheet on which the toner image is transferred is conveyed to the fixing device 170. The CPU 10 controls the temperature of the fixing device 170 to an optimum temperature for the paper according to the detection result of the media sensor 14. Details of the fixing device 170 will be described later. The CPU 10 fixes the toner image on the sheet by the fixing device 170, and then conveys the sheet to the downstream side of the fixing device 170 in the sheet conveying direction. When the leading edge of the sheet after fixing reaches the conveyance sensor 171, the CPU 10 determines whether to convey the sheet to the conveyance path 230 or the conveyance path 231 according to an instruction previously specified from the operation unit 13. The CPU 10 switches the transport destination of the paper by switching the flapper 172 according to the determination. Specifically, the CPU 10 conveys the paper to the conveyance path 230 in the case of the double-sided print instruction, and conveys the paper to the conveyance path 231 in the case of the one-sided print or the back side (second side) of the double-sided print.

Hereinafter, the case where the sheet is conveyed to the conveying path 231 will be described. The sheet transported to the transport path 231 is further transported to the downstream side in the transport direction by the transport roller 232. Here, as in the case of the previous switching, whether the paper is transported to the transport path 180 side or the transport path 181 side by switching the flapper 190 in accordance with the instruction previously designated from the operation unit 13. Can be switched. The sheet is conveyed to the conveyance path 180 when the user's discharge designation destination is the discharge tray 200, and is conveyed to the conveyance path 181 side when the discharge designation destination is the discharge tray 196. The basic image forming operation described above is an example, and the present invention is not limited to the above-described configuration.

<Explanation of the fixing device 170>
FIG. 3 is a diagram for explaining the configuration of the fixing device 170, and shows a state in which the sheet S carrying the toner T is conveyed to the fixing device 170 in the direction of the arrow in the figure. The fixing device 170 includes a heater holder 207, a fixing heater 204, and a fixing film 203. The fixing heater 204 is fixedly provided on the lower surface of the heater holder 207 along the longitudinal direction of the heater holder (the direction orthogonal to the drawing and also the direction orthogonal to the sheet conveyance direction). The fixing film 203 has an elastic layer. The pressure roller 205 is arranged such that both ends of the cored bar are rotatably supported between the side plates of the fixing device 170. The fixing device 170 is arranged in parallel with the pressure roller 205 so that the fixing heater 204 side is in contact with the pressure roller 205, and both end sides of the heater holder 207 are pressed with a predetermined pressing force by urging means (not shown). It is in a state.

As a result, the surface of the fixing heater 204 is pressed against the elasticity of the pressure roller 205 with the fixing film 203 interposed therebetween to form a fixing nip portion 206 having a predetermined width. The pressure roller 205 is rotationally driven at a predetermined peripheral speed in the arrow direction (counterclockwise direction) by a drive mechanism (not shown). The fixing heater 204 is formed by forming a resistance heating element on a ceramic substrate. The thermistor 208 is in contact with the fixing heater 204. The CPU 10 detects the temperature of the fixing heater 204 by the thermistor 208 and controls the electric power supplied to the fixing heater 204 so that the temperature of the fixing heater 204 reaches a predetermined temperature.

The target temperature of the fixing heater 204 is determined by the type of paper and the environmental temperature. The CPU 10 determines the target temperature of the fixing heater 204 according to the type of medium set by the operation unit 13 or the type of medium detected by the medium sensor 14. At this time, if the environmental temperature and the like are further known, the CPU 10 generally takes into consideration the environmental temperature and corrects the target temperature of the fixing heater 204.

<Explanation of the media sensor 14>
Next, an example of the media sensor 14 will be described with reference to FIG. Inside the media sensor 14, there is a sensor unit 470 in which an LED 481 as a light emitting element and a photodiode 480 as a light receiving element are arranged. The photodiode 480 is capable of detecting the light amount (reflected light amount) of the light that is emitted from the LED 481 onto the object (paper S) and reflected from the object. Further, the guide portion 483 into which the paper S is pushed is pressed toward the paper by a spring 482 which is a pressing unit. The pressing force of the spring 482 is changed by the cam 484 rotated by a driving unit (not shown). When the cam 484 is rotating in the direction in which the effective length of the spring 482 is shortened, the pressing force with which the spring 482 presses the guide portion 483 is strong, and the cam 484 is rotated in the direction in which the effective length of the spring 482 is increased. When it is present, the pressing force of the spring 482 pressing the guide portion 483 is weak. While the material of the paper S is detected by the media sensor 14, the cam 484 is rotationally driven, and the pressing force of the spring 482 is changed.

FIGS. 4B to 4E are schematic views showing, as an example, how thin paper and thick paper are conveyed. FIG. 4B shows a state in which the pressing force of the spring 482 is weak during thin paper conveyance, and FIG. 4C shows a state in which the pressing force of the spring 482 is strong during thin paper conveyance. When the thin paper is being conveyed, the thin paper is stably conveyed with respect to the guide portion 483 regardless of the pressing force of the spring 482. On the other hand, FIG. 4D shows a state where the pressing force of the spring 482 is weak during the conveyance of thick paper, and FIG. 4E shows a state where the pressing force of the spring 482 is strong during the conveyance of thick paper. When the pressing force of the spring 482 is weak, the cardboard 483 having a strong elasticity presses the guide portion 483. On the other hand, when the pressing force of the spring 482 is strong, the pressing force of the spring 482 and the guide portion 483 press the thick paper S to the sensor unit 470, which is a stable state.

Next, a plot 250 of the amount of reflected light obtained by the photodiode 480 when the paper S is thin paper is shown in FIG. 5A, and a plot of the amount of reflected light obtained by the photodiode 480 when the paper S is thick paper. 255 is shown in FIG. In FIG. 5, the horizontal axis represents time, and the vertical axis represents the amount of reflected light obtained by the photodiode 480. From timings t11 and t12, the pressing force of the spring 482 is weak (FIGS. 4B and 4D). The state is changed to a strong state (FIGS. 4C and 4E). The amount of reflected light obtained when the sheet S is a thin sheet is stably conveyed along the guide portion 483 regardless of the pressing force of the spring 482 (251, 252). Therefore, before and after the timing t11, neither the average value of the reflected light amount nor the difference between the maximum value and the minimum value (hereinafter referred to as the amplitude) of the reflected light amount changes (250).

On the other hand, the amount of reflected light obtained when the paper S is thick paper changes from a state where the pressing force of the spring 482 is weak (256) to a strong state (timing 257) at timing t12, as compared with the state where the pressing force of the spring 482 is weak. The value increases and the amplitude of the reflected light amount decreases (255). The average value here does not mean the average value in each range such as the average value in the state where the pressing force is weak and the average value in the state where the pressing force is strong. It is an average value in the entire range shown in the figure including the same, and the same applies to FIG. 6B described later. As for the amount of reflected light obtained when the paper is thick paper, the average value of the amount of reflected light and the magnitude of the amplitude change depending on the pressing force of the spring 482. This is because when the pressing force of the spring 482 is weak (256), the paper S is not stably conveyed along the guide portion 483, whereas when the pressing force of the spring 482 is strong (257), the paper S is strong. Is stably conveyed along the guide portion 483.

The CPU 10 receives the input signal of the photodiode 480 as the output value of the media sensor 14. The CPU 10 detects the amount of reflected light detected by the media sensor 14 when the paper S is pressed by the spring 482 with a predetermined force, and the amount of reflected light detected by the media sensor 14 when the paper S is pressed with a force stronger than the predetermined force. The type of paper S is determined based on the amount of reflected light. In this way, the CPU 10 can determine the type of the sheet being conveyed (material, thickness, etc. of the sheet S) based on the output value of the media sensor 14 for each sheet S. The CPU 10 optimally controls the temperature of the fixing device 170 in accordance with the type of paper determined based on the detection result of the media sensor 14. Further, the CPU 10 stores the determined paper type in the storage unit 15. When there are a plurality of paper feed units, the CPU 10 may be configured to store paper type information in the storage unit 15 for each paper feed unit.

Note that, as described above, the media sensor 14 described in the present embodiment is arranged on the transport path, and has a configuration in which the paper type is detected by the paper S passing through the position facing the media sensor 14. is there. Therefore, the CPU 10 stops the conveyance of the sheet S when the type of the sheet detected by the media sensor 14 is different from the type of the sheet set by the operation unit 13. In this case, the user needs to remove the stopped sheet S. Further, the CPU 10 has a configuration in which the image forming operation needs to be performed again after the paper is removed by the user.

The example of the configuration of the media sensor 14 used in the present embodiment has been described above. The configuration of the media sensor 14 described here is an example, and the present invention is not limited to this configuration. For example, a method of combining an ultrasonic sensor such as a piezoelectric element in addition to the light emitting element and the light receiving element described in this embodiment is also effective. In the case of such a configuration, it is possible to detect the basis weight and the like of the paper using the reception signal of the ultrasonic sensor, and it is possible to determine the paper type with higher accuracy. The present invention is an effective configuration even for the media sensor 14 having those other configurations.

<Automatic detection mode and instruction mode>
(Automatic detection mode)
Next, the automatic detection mode which is the second mode of the present embodiment and the instruction mode which is the first mode will be described with reference to FIG. In FIG. 6, the horizontal axis indicates time, and indicates an event that occurs in the image forming apparatus 100, such as the start of a print operation, or the timing when the paper reaches the media sensor 14. Further, the vertical axis of FIG. 6 shows control targets such as fixing control and sheet conveyance control.

The operation when the automatic detection mode is set by the operation unit 13 will be described with reference to FIG. When an operation start instruction is input from the operation unit 13 at the timing t1, the CPU 10 starts the paper conveyance control. At this time, since the actual type of paper is unknown, control of the fixing device 170 is not started. After that, the CPU 10 monitors the paper feed pickup sensor 152 and the like, and waits for the paper to reach the media sensor 14. After the leading edge of the paper reaches the media sensor 14 at the timing t2, the CPU 10 determines the paper type of the conveyed paper based on the detection result of the media sensor 14 by the control described above. When the determination of the sheet type using the media sensor 14 is completed, the CPU 10 sets the target temperature for the fixing device 170 according to the determined sheet type of the sheet and starts the fixing start-up control.

When it is determined that the temperature of the fixing device 170 is lower than the target temperature when the fixing start-up control is started, and the temperature does not reach the target temperature by the time the sheet reaches the fixing nip portion 206 of the fixing device 170, The CPU 10 temporarily stops the conveyance of the paper. The CPU 10 waits until the temperature of the fixing device 170 reaches the target temperature ((X) in FIG. 6). Then, at the timing t3 when the temperature of the fixing device 170 reaches the target temperature, the CPU 10 performs the paper conveyance control for driving the motor to restart the paper conveyance. Further, the CPU 10 performs a fixing temperature control for controlling the temperature of the fixing device 170 to be maintained at the target temperature, and when the sheet reaches the fixing device 170 at timing t4, the fixing process is performed.

As described above, in the automatic detection mode, the user does not need to be aware of or select the paper type when manually setting, but the fixing start-up operation cannot be started until the paper type is known. The formation end timing is delayed. There is also a method of accelerating the fixing start-up control in the automatic detection mode based on the detection result of the media sensor 14 performed in the past. However, in a state where the paper type is uncertain, such as immediately after opening and closing the paper feed cassette 220 or immediately after turning on the power of the image forming apparatus 100, the fixing device is not fixed until the paper type is fixed. The startup operation of 170 cannot be started. In this case also, the image formation may be delayed.

(Instruction mode)
Next, the operation when the operation unit 13 is set to the instruction mode will be described with reference to FIG. When a paper type is selected from the operation unit 13 and an operation start instruction is input at timing t5, the CPU 10 starts the paper transport operation. Further, since the paper type is selected at the timing t5, the target temperature for the fixing device 170 is fixed at this point. Therefore, at the timing t5, the CPU 10 starts the sheet conveying operation and the start-up operation for the fixing device 170. The CPU 10 monitors the conveyance sensor such as the paper feed pickup sensor 152 and the thermistor 208.

The CPU 10 shows an example in which the temperature detected by the thermistor 208 reaches the target temperature at the timing t6 and the leading edge of the sheet reaches the media sensor 14 at the timing t7. In this way, when the paper reaches the media sensor 14 after the temperature of the fixing device 170 reaches the target temperature, the CPU 10 stops the paper at the timing when the determination of the paper type using the media sensor 14 is completed. The operation can be continued without any action. This is because the temperature of the fixing device 170 has already reached the target temperature at the timing t8 when the paper reaches the fixing device 170. Therefore, in the instruction mode, since the waiting time unlike the (X) in the automatic detection mode (FIG. 6A) does not occur, it is possible to shorten the time from the start of the printing operation (timing t5) until the sheet is ejected. Is possible.

As described above, in the instruction mode, it is necessary for the user to be aware of and select the type of paper, while the fixing start-up operation can be performed at the fastest speed. As a result, it is possible to perform the image formation end timing at the highest speed.

The image forming apparatus 100 according to the present embodiment is provided with both the automatic detection mode and the instruction mode as described above, so that the image forming apparatus 100 can be adapted to a user who does not want to perform the setting operation in consideration of the paper type. It is possible. Further, even if it is necessary to set the paper type in consideration, it is possible to cope with the user who needs the product at the fastest speed.

The above-described embodiment is an example, and the present invention is not limited to this. For example, the instruction of the automatic detection mode and the instruction mode may be set on a personal computer having a printer driver other than the operation unit 13. Further, in the above-described embodiment, the fixing start-up control has been described as an example of the cause of the problem that the timing of ending image formation is delayed in the automatic detection mode. However, the present invention is not limited to this. If the control requires time as a preparatory operation for the image forming operation, a similar problem occurs. For example, the same problem exists in an image forming apparatus that requires an operation for determining the voltage value applied to the secondary transfer unit 140 according to the type of paper.

<Explanation of Flowchart for Identifying Incorrect Paper Type Instruction>
Next, it is a feature of the present embodiment that the set paper type and the paper type detected by the media sensor 14 do not match before the paper feeding operation starts (hereinafter referred to as paper type mismatch). A method for determining is described with reference to the flowchart in FIG. When the user selects the instruction mode from the operation unit 13 to select the type of paper to be conveyed and the operation start instruction is input, the CPU 10 starts the operation of step (hereinafter referred to as S) 300 and subsequent steps. To do. In S300, the CPU 10 starts a print job in the instruction mode. In S301, the CPU 10 acquires the paper type set by the user.

(When the detection result of the media sensor is stored in the storage unit)
In S302, the CPU 10 determines whether or not the detection result of the paper by the media sensor 14 is stored in the storage unit 15. When the CPU 10 determines in S302 that the storage unit 15 has a sheet detection result, the process proceeds to S303. In S303, the CPU 10 determines whether or not the type of paper acquired in S301 and the detection result of the paper stored in the storage unit 15, in other words, the past detection result match. If the CPU 10 determines in S303 that the type of paper set from the operation unit 13 and the detection result of the paper stored in the storage unit 15 do not match, the process proceeds to S312.

In this case, there is a possibility that the type of paper set by the user does not match the type of paper detected by the media sensor 14 in the past, in other words, the type of paper in the paper feed cassette 220. In step S312, the CPU 10 causes the operation unit 13 or the like to display a message indicating that there is a possibility that the user's settings are incorrect, notifies the user, and ends the process. In this way, the operation unit 13 also functions as a notification unit. FIG. 8A is a diagram showing an example of a screen displayed on the operation unit 13. By displaying the screen as shown in FIG. 8A on the operation unit 13, the user is prompted to confirm the setting of the paper type and the paper in the paper feed cassette 220. In this case, the CPU 10 does not start the operation (print operation) of the paper feed motor 150, the image forming unit 17, and the like.

By performing the above operation, in the instruction mode, and when the detection result by the media sensor 14 is stored in the storage unit 15, the paper type mismatches before the paper feeding operation by the paper feeding motor 150. It becomes possible to judge. As a result, the operation of removing the paper stopped on the conveyance path, which is necessary when it is determined that the paper types do not match after the paper feed is started, is eliminated, and usability is improved.

If the CPU 10 determines in step S303 that the detection result stored in the storage unit 15 matches the type of paper set by the user, the process proceeds to step S305. In step S305, the CPU 10 starts printing operation such as paper feeding operation and image forming operation. In step S306, the CPU 10 performs a sheet detection operation by the media sensor 14 for each page of the sheet, and determines the type of sheet being conveyed. This is performed so that the paper in the paper feed cassette 220 can be handled even when different types of paper are erroneously mixed. Further, the CPU 10 stores information on the amount of reflected light detected by the media sensor 14 in the storage unit 15. Note that the CPU 10 may be configured to store in the storage unit 15 information regarding the type of paper determined based on the amount of reflected light detected by the media sensor 14. In the present embodiment, it is assumed that the storage unit 15 stores the reflected light amount detected by the media sensor 14.

In S308, the CPU 10 determines whether or not the paper type set by the user and the paper type determined based on the detection result of the media sensor 14 in S306 match. If the CPU 10 determines in step S308 that the type of sheet set by the user does not match the determination result of the type of sheet by the media sensor 14, the process proceeds to step S309. In S309, the CPU 10 stops the printing operation. In step S313, the CPU 10 causes the operation unit 13 or the like to display a message notifying that different types of paper are mixed in the paper feed cassette 220, and ends the processing. An example of the screen displayed on the operation unit 13 in S313 is shown in FIG. For example, the CPU 10 causes the operation unit to display that printing has been interrupted, that the type of paper has changed, etc., and prompts the user to confirm the setting of the paper type and the paper in the paper feed cassette 220.

If the CPU 10 determines in S308 that the type of paper set by the user and the determination result of the type of paper by the media sensor 14 match, the CPU 10 continues the operation and determines in S310 whether or not it is the final page. When the CPU 10 determines in S310 that the page is the last page, the CPU 10 terminates printing in S311 and terminates the process. If the CPU 10 determines in S310 that the page is not the final page, the process returns to S306.

(When the detection result of the media sensor is not stored in the storage unit)
The operation when the instruction mode is selected and the detection result of the media sensor 14 is not stored in the storage unit 15 will be described with reference to the flowchart of FIG. 7. When the CPU 10 determines in S302 that the detection result of the media sensor 14 is not stored in the storage unit 15, the process proceeds to S304. In step S304, the CPU 10 starts the paper feeding operation and the image forming operation, and when the standby state such as the fixing control and the high voltage control described above is shifted to the printing state according to the type of the sheet set by the user. The process (referred to as pre-rotation process) is started, and the process proceeds to S305. In step S<b>305, the CPU 10 starts printing and waits for the sheet conveyed by the sheet feed pickup roller 151 to reach the media sensor 14. When the paper reaches the media sensor 14 in S306, the CPU 10 performs a paper type determination process using the media sensor 14. Since the processing after S308 has been described above, the description thereof will be omitted.

If the detection result of the paper type is not stored in the storage unit 15 and the paper type set by the user in the process of S308 does not match the paper type determined by the media sensor 14, , S309, the CPU 10 stops the printing operation. In this case, when the type of paper is determined by the media sensor 14 and the printing operation is stopped, it is necessary to remove the paper stopped on the transport path as described above.

As described above, according to the present embodiment, usability can be improved even when the set paper type does not match the paper type stored in the storage unit.

10 CPU
13 operation unit 14 media sensor 15 storage unit 151 paper feed pickup roller

Claims (7)

Paper feeding means for feeding the recording media stacked in the paper feeding section,
Detection means for detecting the type of recording medium fed by the paper feeding means;
Setting means for manually setting the type of recording medium,
The printing operation is controlled by either a first mode in which the printing operation is controlled based on the type of the recording medium set by the setting means or a second mode in which the printing operation is controlled based on the detection result by the detection means. Control means,
Storage means for storing information on the type of recording medium detected in the past by the detection means;
Equipped with
The control means, when instructed to start the printing operation in the first mode, information on the type of the recording medium set by the setting means and the type of the recording medium stored in the storage means. When the type of the recording medium determined based on the above does not match, control is made not to start the feeding of the recording medium by the sheet feeding means , and the set type of the recording medium and the determined type of the recording medium. , The printing operation is started, the recording medium is fed from the paper feeding unit by the paper feeding unit, and the recording medium fed from the paper feeding unit is detected by the detection unit. An image forming apparatus , wherein the detection result is stored in the storage unit. Equipped with informing means for informing information,
The control unit causes the notification unit to notify that the setting of the type of the recording medium by the setting unit does not match the type of the recording medium loaded in the paper feeding unit. The image forming apparatus described. The image according to claim 2 , wherein the control unit stops the printing operation when the type of the set recording medium does not match the type of the recording medium detected by the detecting unit. Forming equipment. Equipped with informing means for informing information,
The image forming apparatus according to claim 3 , wherein the control unit causes the notification unit to notify that there is a possibility that different types of recording media are mixed in the paper feeding unit. 2. The detection unit includes a light emitting element that irradiates a recording medium with light, and a light receiving element that detects the amount of light emitted from the light emitting element to the recording medium and reflected from the recording medium. The image forming apparatus according to claim 4 . The detection means has a pressing means for pressing the recording medium in the direction in which the light emitting element and the light receiving element are arranged, and the amount of reflected light detected when the recording medium is pressed by the pressing means with a predetermined force. when the amount of reflected light detected when it is pressed by a strong force than said predetermined force by the pressing means, on the basis of, according to claim 5, characterized in that to determine the type of the recording medium Image forming apparatus. Paper feeding means for feeding the recording media stacked in the paper feeding section,
Detection means for detecting the type of recording medium fed by the paper feeding means;
Setting means for manually setting the type of recording medium,
The printing operation is controlled by either a first mode in which the printing operation is controlled based on the type of the recording medium set by the setting means or a second mode in which the printing operation is controlled based on the detection result by the detection means. Control means,
Storage means for storing information on the type of recording medium detected in the past by the detection means;
Equipped with
The control means, when instructed to start the printing operation in the first mode, information on the type of the recording medium set by the setting means and the type of the recording medium stored in the storage means. When the type of the recording medium determined based on the above does not match, control is performed so that the feeding of the recording medium by the sheet feeding unit is not started, and the information regarding the type of the recording medium is not stored in the storage unit. , said according to the type of set recording medium by setting means, images forming device characterized in that to start the printing operation.

Images