The present disclosure relates to an electrophotographic image forming apparatus.
Heretofore, in an electrophotographic image forming apparatus having a sheet type determination function for reducing a burden of setting image forming conditions on a user, optimum image forming conditions are set according to the sheet determination result, thereby realizing power saving and image quality improvement. For example, Japanese Patent Application Laid-Open No. 2009-29622 discloses an image forming apparatus that detects a basis weight (mass per unit area) of a sheet from a transmittance of an ultrasonic wave applied to the sheet and determines a sheet type on the basis of a result of detecting the basis weight. In addition, as one maintenance function, there is known an image forming system that identifies an abnormal place in an image forming apparatus by detecting a sound generated when the image forming apparatus operates to form an image. Japanese Patent Application Laid-Open No. 2020-160237 discloses an image forming apparatus in which one receiving member serves as an ultrasonic receiver configured to detect a basis weight of a sheet and a sound collector configured to identify an abnormality.
However, in the multi-purpose configuration of the one receiving member described in Japanese Patent Application Laid-Open No. 2020-160237, it is difficult to simultaneously detect the basis weight of the sheet and the operating sound. Therefore, in a period during which a certain sheet (recording material) is conveyed between an ultrasonic wave transmitting member and an ultrasonic wave receiving member, a control may be performed to detect an operating sound in the first half period and detect a basis weight in the second half period. However, even in the second half period, there is a possibility that an abnormal sound may occur resulting from the conveyance of the sheet. Therefore, a control may be performed so that an abnormal sound can be detected at any timing during the conveyance of the sheet by either detecting an operating sound or detecting a basis weight for each sheet in a specific cycle. That is, only basis weight detection is performed in a period in which a certain sheet is conveyed, and only operating sound detection is performed in a period in which another sheet is conveyed.
However, in a case in which the control is performed to switch for each sheet to the detection of the operating sound or the detection of the basis weight, a result of the detection of the basis weight may deviate due to the cycle characteristic of properties. A sheet bundle used in an image forming apparatus is generally made by stacking sheets cut from a plurality of rolls. It is known that properties (basis weights) of a plurality of sheets cut from one roll slightly change with a specific cycle characteristic. Therefore, when the sheets in the bundle are sequentially investigated, properties of a plurality of sheets cut from a first roll change in a certain cycle, and properties of a plurality of sheets cut from a second roll change in another certain cycle. Here, in a case in which the cycle in which the properties change coincidentally coincides with a cycle in which an operating sound is detected, there is a possibility that deviation to one side may occur in the results of detecting the basis weights as compared with those in a case in which the cycle in which the properties change does not coincide with the cycle in which the operating sound is detected. Then, as the results of detecting the basis weights deviate to one side, for example, it may cause a problem in that a target temperature of the fixing device is lowered by several ° C., which causes an image defect, or conversely, the target temperature is raised by several ° C., which causes an increase in power consumption of the fixing device.
Disclosed herein is an image forming apparatus that works towards achieving both accurate detection of properties of recording materials and detection of operating sounds.
An image forming apparatus includes a stack portion on which recording materials are to be stacked, a feeding unit configured to feed each of the recording materials stacked on the stack portion, an image forming unit configured to form an image on each of the recording materials fed by the feeding unit, a transmitter configured to transmit an ultrasonic wave, a receiver configured to receive the ultrasonic wave transmitted from the transmitter via the recording material and an operating sound generated in the image forming apparatus, a basis weight detection unit configured to detect a basis weight of the recording material based on an output from the receiver when the receiver receives the ultrasonic wave, an operating sound detection unit configured to detect an abnormality of the operating sound based on an output from the receiver when the receiver receives the operating sound, and a mode selection unit configured to select, for each of the recording materials fed to the image forming unit, between transmitting to the basis weight detection unit a first instruction for detecting the basis weight of the recording material and transmitting to the operating sound detection unit a second instruction for detecting the abnormality of the operating sound, wherein, in determining an interval at which each second instruction is transmitted, the mode selection unit determines the interval so that the interval and a cycle, in which properties of the recording materials stacked on the stack portion are repeated, do not continuously coincide.
Further features of the present disclosure will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Hereinafter, the embodiments of the present disclosure will be exemplarily described in detail with reference to the accompanying drawings. However, dimensions, materials, shapes, relative arrangements, and the like of components to be described below should be appropriately changed according to a configuration of an apparatus to which the present disclosure is applied and various conditions. Therefore, unless otherwise specified, the scope of the present disclosure is not limited thereto.
An electrophotographic color image forming apparatus to which the present disclosure is applicable will be described.
Each of the process cartridges 22 includes a photosensitive drum 5 as an image bearing member, a charging unit 7 configured to charge a surface of the photosensitive drum 5 to a uniform potential, and a developing unit 8 configured to form a toner image by attaching the toner to an electrostatic latent image formed on the photosensitive drum 5. Each of the process cartridges 22 is detachably mounted to the printer 203. The photosensitive drum 5 is formed by applying an organic photoconductive layer to an outer circumference of an aluminum cylinder, and is driven by a drive motor (not shown) to rotate in a direction (clockwise direction) indicated by an arrow in
While forming an image, the intermediate transfer belt 12 rotates in a direction (counterclockwise direction) indicated by an arrow in
The cassette tray 101 is a stack portion on which sheets 2 as recording materials are accommodated and stacked. When an electromagnetic clutch (not shown) is set to a turn-on state, a driving force from a motor (not shown) is transmitted to a feed roller 102. Then, the feed roller 102 rotates in the counterclockwise direction in
The fixing unit 13 as a fixing portion is a unit configure to fix the toner image transferred on the sheet 2 as well as conveying the sheet 2 to which the toner image has been transferred in the transfer nip portion. The fixing unit 13 includes a fixing roller 14 configured to heat the sheet 2, and a pressing roller 15 configured to bring the sheet 2 into pressure contact with the fixing roller 14 while conveying the conveyed sheet 2. The fixing roller 14 and the pressing roller 15 are formed in a hollow shape, and a heater configured to heat the sheet 2 is built in the fixing roller 14. The sheet 2 to which the unfixed toner image has been transferred is conveyed while being heated and pressurized by the fixing roller 14 and the pressing roller 15, thereby fixing the toner image onto the surface of the sheet 2. The sheet 2 onto which the toner image has been fixed is discharged to a discharge tray 27 by a discharge roller 52, and the image forming operation is completed. A fixing discharge sensor 17 is disposed downstream of the fixing unit 13 in the direction in which the sheet 2 is conveyed, and the fixing discharge sensor 17 detects the sheet 2 having passed through the fixing unit 13.
On the conveying path 25 between the registration sensor 16 and the transfer nip portion, a transmitter 31 configured to transmit an ultrasonic wave and a receiver 71 configured to receive the ultrasonic wave transmitted by the transmitter 31 are arranged opposite to each other with the conveying path 25 interposed therebetween. The transmitter 31 includes a piezoelectric element (also referred to as the piezo element), which is an element for conversion between a mechanical displacement and an electric signal, and an electrode terminal. On the other hand, the receiver 71 includes a micro electro mechanical system (MEMS) microphone and an electrode terminal, the MEMS microphone converting a vibration displacement of a diaphragm caused by pressure into a voltage change and outputting the voltage change. In addition, an operation display unit 205 configured to operate an input and display information is provided in an upper portion of the printer 203.
The engine controller 206 includes a CPU 207, a ROM 208, and a RAM 209. Using the RAM 209 as a work area, the CPU 207 controls the printer 203 on the basis of a program and various data stored in the ROM 208. An actuator (not shown) controlling each unit for forming an image as explained with reference to
Next, functions of the engine controller 206 related to detecting a basis weight of the sheet 2 and detecting an operating sound of the printer 203 will be described.
The image forming controller 200 controls an operation of forming an image on the sheet 2 such as controlling each process cartridge 22 and the scanner unit 10 and controlling the feeding of the sheet 2 from the cassette tray 101, and includes an image forming condition switching portion 300 and a receive mode selection portion 301. The image forming condition switching portion 300 switches image forming conditions at the time of forming an image on the sheet 2 on the basis of a result of detecting the basis weight of the sheet 2, which is acquired from the basis weight detection controller 302. In addition, the receive mode selection portion 301 instructs the basis weight detection controller 302 to start detecting a basis weight for detecting the basis weight of the conveyed sheet 2, and instructs the operating sound detection controller 305 to start detecting an operating sound for detecting the operating sound of the printer 203.
The basis weight detection controller 302 includes an ultrasonic transmitter 303 and an ultrasonic receiver 304. The ultrasonic transmitter 303 instructs the transmitter 31 to transmit an ultrasonic wave. The ultrasonic receiver 304 calculates a basis weight of the conveyed sheet 2 on the basis of an output signal from the receiver 71 that receives an ultrasonic wave transmitted from the transmitter 31 in response to an instruction from the receive mode selection portion 301, and stores the basis weight information. In response to a request from the image forming controller 200, the basis weight detection controller 302 transmits the basis weight information of the sheet 2 stored in the ultrasonic receiver 304 to the image forming controller 200.
The operating sound detection controller 305 includes an operating sound receiver 306. The operating sound receiver 306 generates operating sound information on the basis of an output signal regarding an operating sound of the printer 203 detected by the receiver 71. In response to an instruction from the receive mode selection portion 301, the operating sound detection controller 305 transmits the operating sound information generated by the operating sound receiver 306 to the operating sound diagnostic controller 308.
The operating sound diagnostic controller 308 determines whether or not there is an abnormality in the operating sound of the printer 203 on the basis of the operating sound information acquired from the operating sound detection controller 305. When it is determined that there is an abnormality in the operating sound of the printer 203, the operating sound diagnostic controller 308 transmits state information of the printer 203 to the video controller 204. On the basis of the state information of the printer 203 received from the operating sound diagnostic controller 308 of the engine controller 206, the video controller 204 displays the state of the printer 203 on the operation display unit 205 and transmits the state information of the printer 203 to the host computer 100. The function of each of the functional blocks described above is implemented by the CPU 207 of the engine controller 206 executing the program stored in the ROM 208.
Next, a basis weight detection control according to the present embodiment will be described.
In
The basis weight detection controller 302 includes a communication controller 404, an ultrasonic transmitter 303, and an ultrasonic receiver 304. Upon receiving an instruction to start detecting a basis weight of the sheet 2 from the receive mode selection portion 301 of the image forming controller 200 via the communication controller 404, the ultrasonic transmitter 303 instructs a drive signal generator 405 to generate a drive signal for detecting the basis weight. Upon receiving an instruction to generate a drive signal, the drive signal generator 405 generates a drive signal and outputs the drive signal to the transmitter 31. The transmitter 31 outputs an ultrasonic wave according to the drive signal output from drive signal generator 405. On the other hand, when receiving the ultrasonic wave transmitted from the transmitter 31, the receiver 71 outputs the ultrasonic wave to the ultrasonic receiver 304 of the basis weight detection controller 302. The transmission of the ultrasonic wave from the transmitter 31 is performed in a state in which the sheet 2 does not exist (in a state in which the sheet 2 has not been conveyed) and in a state in which the sheet 2 exists (in a state in which the sheet 2 is passing) on the conveying path between the transmitter 31 and the receiver 71.
The ultrasonic receiver 304 includes an A-D converter 400, a peak detector 401, a storage unit 402, and a calculation unit 403. The A-D converter 400 receives an analog signal output from the receiver 71, converts the input analog signal into a digital signal, and outputs the digital signal to the peak detector 401. The peak detector 401 receives the digital signal output from the A-D converter 400, detects a peak value (maximum value) of the input digital signal, and causes the storage unit 402 to store the peak value therein. In addition, the peak detector 401 causes the storage unit 402 to store peak values of digital signals in the state in which the sheet 2 does not exist and in the state in which the sheet 2 exists at a detection position 450 on the conveying path between the transmitter 31 and the receiver 71. The calculation unit 403 calculates an attenuation coefficient (a value corresponding to the basis weight of the sheet 2) of the conveyed sheet 2 from a ratio between the peak value of the digital signal in the state in which the sheet 2 does not exist and the peak value of the digital signal in the state in which the sheet 2 exists, the peak values being stored in the storage unit 402, and stores the attenuation coefficient in the storage unit 402. The image forming condition switching portion 300 of the image forming controller 200 acquires the attenuation coefficient information of the sheet 2 stored in the storage unit 402 of the ultrasonic receiver 304 via the communication controller 404, and switches conditions for forming an image on the sheet 2 on the basis of the acquired attenuation coefficient information. The conditions for forming an image on the sheet 2 are changed according to the basis weight which is the attenuation coefficient information of the sheet 2. The image forming conditions in the present embodiment are, for example, a conveyance speed of the sheet 2, a voltage applied to the secondary transfer roller 9, and a target temperature of the heater in the fixing unit 13.
Next, an operating sound detection control according to the present embodiment will be described.
The operating sound detection controller 305 includes the operating sound receiver 306 and a communication controller 413. Upon receiving an instruction to start detecting an operating sound from the receive mode selection portion 301 of the image forming controller 200 via the communication controller 413, the operating sound detection controller 305 starts an operating sound detection control in the printer 203. The operating sound receiver 306 includes an A-D converter 410, a digital filter calculation unit 411, a calculation unit 414, and a storage unit 412.
The A-D converter 410 receives an analog signal (voltage signal) output from the receiver 71, converts the input analog signal into a digital signal, and outputs the digital signal to the digital filter calculation unit 411. In order to increase detection accuracy, the digital filter calculation unit 411 applies a filter suitable for an operating sound of a target member selected in advance by the receive mode selection portion 301 to the digital signal input from the A-D converter 410. The digital filter calculation unit 411 generates a signal through filter calculation (filter processing), in which only an operating sound in a specific frequency domain is extracted from the digital signal input from the A-D converter 410, and outputs the generated signal to the calculation unit 414. The calculation unit 414 performs square calculation or interval average calculation with respect to the signal subjected to the filter calculation in the digital filter calculation unit 411 in order to facilitate comparison in sound magnitude at the time of diagnosing an abnormal sound. In the present embodiment, an interval in which the interval average calculation is performed is set to 100 ms (milliseconds), but is not limited thereto. For example, a plurality of intervals may be provided to be selectable, or the interval may be set arbitrarily. The signal subjected to the interval average calculation is stored in the storage unit 412 as a signal level of the operating sound.
The operating sound diagnostic controller 308 acquires the operating sound data stored in the storage unit 412 of the operating sound receiver 306 via the communication controller 413, and determines whether the signal level of the acquired operating sound data exceeds an abnormality determination threshold value selected in advance for a member that needs to be diagnosed. When the signal level of the acquired operating sound exceeds the abnormality determination threshold value, the operating sound diagnostic controller 308 diagnoses that an abnormal sound is generated in the member that needs to be diagnosed. Thereafter, the operating sound diagnostic controller 308 instructs the engine controller 206 to perform a control to suppress the generation of the abnormal sound, displays a place in which the abnormal sound is generated on the operation display unit 205, notifies a maintenance center via a network to which the printer 203 is connected of the state of the printer 203, and the like.
As described above, a sheet bundle for a printer used in an office is often made by stacking sheets cut from a plurality of rolls. In a case in which properties are different from each other from roll to roll, a sheet bundle created from the plurality of rolls has a cycle characteristic in which change in the properties are periodic. Therefore, when such the sheet bundle is placed on the cassette tray 101 and fed at the time of forming images, the sheets having different properties are fed from one sheet feeding port in a certain cycle.
How to view the drawings of
As described above,
Next, a control of the image forming condition switching portion 300 configured to switch the image forming conditions on the basis of the results of detecting the basis weights of the sheets 2 will be described. In the present embodiment, assuming that sheet bundles in which properties (here, basis weights) of the sheets 2 are repeated in 3 sheets cycle to 8 sheets cycle are used, image forming conditions for the sheets 2 are determined using an average value of results of detecting basis weights of the latest eight sheets 2.
In
Although the average value of the latest several-time results of detecting the basis weights is used for setting the fixing temperature in the present embodiment, a maximum value of the basis weights, an average value of weighted basis weights, or the like may be used. In addition, although the image forming condition switching portion 300 uses the basis weight as property information in the present embodiment, the image forming conditions may be determined using the basis weight together with another property information. For example, in order to detect a smoothness of a surface of the sheet 2, the sheet 2 may be irradiated with a light beam. Then, the image forming conditions may be determined using a result of measuring an amount of light reflected from the irradiated light together with the basis weight.
Next, a method in which the receive mode selection portion 301 determines an operating sound detection timing considering a cycle of properties of the sheets 2 will be described. First, with reference to
As illustrated in
The image forming conditions of the printer 203 are designed to be optimal when the basis weights of the sheets 2 are continuously detected without measuring the operating sound. Accordingly, deviations occur in the results of detecting the properties of the sheets 2. As a result, if image formation is continued under the image forming conditions corresponding to the deviated properties, there is a possibility that quality degradation such as an image defect occurs. Specifically, in a case in which image formation is continued at a fixing temperature higher than the expected temperature, the power consumption of the printer 203 increases. On the other hand, in a case in which image formation is continued at a fixing temperature lower than the expected temperature, a temperature at which the sheet 2 is heated in the fixing unit decreases, and accordingly, the toner may fail to be appropriately fixed to the sheet 2. Even though the image forming condition deviates merely at several percent as described above, the influence becomes significant by continuously forming images on the sheets 2. Therefore, it is necessary to prevent the occurrence of the above-described harmful effect by performing a control such that an average basis weight obtained by averaging results of detecting basis weights of a plurality of sheets even in a case in which operating sound measurement is performed is equal to that in a case in which no operating sound measurement is performed.
In the present embodiment, the receive mode selection portion 301 determines an operating sound detection executing interval (executing timing) on the basis of an operating sound detection timing table illustrated in
The values in the table illustrated in
(Condition 1): The values in the table include two or more positive integers, and the sum S of the values is larger than a maximum value Tpmax of an assumed property cycle of the sheets 2.
(Condition 2): The sum S is relatively prime to any of the assumed property cycles Tp of the sheets 2.
(Condition 3): In a case in which a “set” of values constituting the values in the table is divided into two or more groups Gi, the greatest common divisor GCD of a sum Sgi of values of each group and a sum Sgi′ of values of another adjacent group among permutations in the “set” does not coincide with the assumed property cycles Tp of the sheets 2. However, a group including values of which the sum Sgi is larger than the maximum value Tpmax of the property cycles Tp of the sheets 2 is excluded.
Specifically, the set of values {5, 6, 8} illustrated in the table of
In each of the graphs in which the cycles of properties of sheets 2 are 5 to 8 sheets cycles illustrated in
By determining an operating sound detection executing interval with reference to the timings determined on the basis of the above-described conditions 1 to 3 as described above, the receive mode selection portion 301 can prevent the assumed property cycles and the operating sound detection timings from continuously coinciding with each other. Note that, in a case in which it is desired to increase an operating sound detection executing frequency, but it is difficult to satisfy all of the three conditions, a set of the operating sound detection timings satisfying some of the conditions is used. For example, instead of the above-described set {5, 6, 8} of the operating sound detection timings, a set {2, 3, 4} that satisfies only the condition 1 but does not satisfy the conditions 2 and 3 is used. As a result, an effective operating sound detection frequency can be increased from an average interval of about six sheets (≈(5 sheets+6 sheets+8 sheets)/3) to an interval of three sheets (=(2 sheets+3 sheets+4 sheets)/3).
Next, a method in which the receive mode selection portion 301 performs a selection between a basis weight detection control and an operating sound detection control will be described.
In step (hereinafter, referred to as S) 701, the receive mode selection portion 301 determines whether a leading edge of a sheet 2 fed from the cassette tray 101 has reached the registration sensor 16 (Has a leading edge of a sheet reached the sensor?) on the basis of a detection result of the registration sensor 16. When the receive mode selection portion 301 determines that the leading edge of the sheet 2 has reached the registration sensor 16, the processing proceeds to S702, and when the receive mode selection portion 301 determines that the leading edge of the sheet 2 has not reached the registration sensor 16, the processing returns to S701. In S702, the receive mode selection portion 301 adds 1 to a value of the sheet feed count indicating the number of the sheets 2 fed from the cassette tray 101 after the latest operating sound detection is performed.
In S703, the receive mode selection portion 301 acquires a sheet type determination result with respect to the sheet 2 from the image forming controller 200, and determines whether the type of the sheet 2 fed from the cassette tray 101 has been determined (Is there a sheet type determination result?). Here, the sheet type determination result of the image forming controller 200 is a result of determining a type of sheets in a sheet bundle accommodated in the cassette tray 101 on the basis of the result of detecting the property (here, basis weights) of the sheet 2, which is acquired from the basis weight detection controller 302 by the image forming condition switching portion 300. In a case in which the receive mode selection portion 301 determines that the type of the sheet 2 has been determined, the processing proceeds to S704, and in a case in which the receive mode selection portion 301 determines that the type of the sheet 2 has not been determined, the processing proceeds to S707. Note that the determination result of the sheet type of the sheet 2 that the image forming controller 200 has is maintained until an operation of opening/closing the cassette tray 101 is performed after the basis weights of the sheets 2 are detected.
In S704, the receive mode selection portion 301 determines whether the sheet feed count is equal to or larger than the threshold value Tc (Sheet feed count≥threshold value Tc?). Here, the threshold value Tc is a value in the above-described table of
In S705, the receive mode selection portion 301 selects an operating sound detection mode as a receive mode, updates a value set as the threshold value Tc, and resets the sheet feed count so that the sheet feed count is set to 0. Here, in order to update the value, set as the threshold value Tc, a subsequent value (here, 6) of the current threshold value Tc (here, 5) is acquired from the table of
In S707, the receive mode selection portion 301 selects the basis weight detection mode as the receive mode and instructs the basis weight detection controller 302 to start measuring the basis weight (first instruction). Then, the processing proceeds to S708. In S708, the receive mode selection portion 301 acquires print job information from the image forming controller 200, and determines whether or not the print job has been completed (Has the print job been completed?) on the basis of the acquired information. In a case in which the receive mode selection portion 301 determines that the print job has not been completed, the processing returns to S701, and in a case in which the receive mode selection portion 301 determines that the print job has been completed, the processing ends.
In the present embodiment, the method in which the receive mode selection portion 301 selects which detection is to be executed between the basis weight detection and the operating sound detection considering the cycle of properties of the sheets 2 has been described above. By considering the cycle of properties of the sheets 2, it is possible to reduce deviations in the basis weight detection results and execute an operation of forming an image under appropriate image forming conditions on the basis of the basis weight detection results. In addition, by setting a target of operating sound detection to an entire sheet for each sheet 2 (for each recording material), it is possible to detect an abnormal operation sound generated at a certain timing while conveying the sheet 2.
As described above, according to the present embodiment, it is possible to achieve both accurate detection of properties of recording materials and detection of operating sounds.
In the first embodiment, it has been described that the mode selection is performed considering the cycle of properties using the image forming apparatus capable of single-sided printing with one cassette tray serving as a sheet feeding port. In the second embodiment, it will be described that the mode selection is performed considering the cycle of properties using an image forming apparatus including a duplex conveying unit, enabling double-sided printing, with an additional cassette tray, in addition to the configuration of the first embodiment.
Similar to the cassette tray 101, the cassette tray 103 is a stack portion on which sheets 2 as recording materials are accommodated and stacked. When an electromagnetic clutch (not shown) is set to a turn-on state, a driving force from a motor (not shown) is transmitted to a feed roller 104. Then, the feed roller 104 rotates in the counterclockwise direction in
The duplex conveying unit configured to perform double-sided printing on the sheet 2 includes a duplex flapper 50, a duplex conveying path 26, a reverse roller 53, a duplex conveying roller 54, a flapper solenoid (not shown), a reverse motor (not shown), and a duplex motor (not shown). In a case in which the print command from the video controller 204 is the double-sided printing, the flapper solenoid (not shown) is turned on, and a tip of the duplex flapper 50 is oriented in the downward direction of
A configuration of a control unit of the printer 203 of the present embodiment is the same as the configuration of the first embodiment illustrated in
A functional block configuration of an engine controller in the present embodiment is the same as the configuration of the first embodiment illustrated in FIG. 3, and the description thereof will be omitted here. Note that the cassette tray 103 and the duplex conveying unit are added to the printer 203 of the present embodiment. Thus, at the time of an image forming operation in response to a print command from the video controller 204, the image forming controller 200 performs a control to feed the sheet 2 from the cassette tray 101 or the cassette tray 103. In addition, in a case in which the print command from the video controller 204 is the double-sided printing, the image forming controller 200 performs a control to turn on and off the flapper solenoid (not shown) depending on whether to print the first surface or the second surface of the sheet 2. Accordingly, the image forming controller 200 performs a control to switch where the sheet 2 is to be conveyed (discharge roller 52 or reverse roller 53).
In addition to the above-described control, the image forming controller 200 of the present embodiment starts the image forming operation after confirming the arrival of the sheet 2 in the registration sensor 16 in order to suppress the consumption of the toner when a sheet jamming has occurred. In this case, the sheet 2 reaches the secondary transfer roller 9 before the toner image on the intermediate transfer belt 12 reaches the transfer nip portion. For this reason, the image forming controller 200 executes a registration stop conveyance control (first conveyance mode) to temporarily stop the conveyance of the sheet 2 in front of the secondary transfer roller 9 and then resume the conveyance. The image forming controller 200 performs not only the registration stop conveyance control but also a registration non-stop conveyance control (second conveyance mode) to convey the sheet 2 to the transfer nip portion without temporarily stopping the conveyance of the sheet 2 in front of the secondary transfer roller 9. The image forming controller 200 of the present embodiment performs the registration stop conveyance control with respect to a first sheet 2 in a print job at all times.
When the operating sound measurement is performed with respect to the sheet 2 conveyed under the registration stop conveyance control, there is an advantage in that the operating sound measurement focusing on operating sounds other than those generated during the conveyance control can be performed. Specifically, while the conveyance of the sheet 2 is temporarily stopped under the registration stop conveyance control, the following sounds are not generated: sounds when the sheet 2 slides on the conveying path; sounds when the registration roller 3 and the conveying roller 40 rotate; and sounds when the motor, which is a drive source, is activated and a gear transmitting a driving force of the motor to each of the rollers is driven. Accordingly, sounds generated when other image forming units are driven (e.g., sounds when the intermediate transfer belt 12, the photosensitive drum 5, the fixing unit 13, and the like rotate) can be detected relatively, enabling the operating sound diagnostic controller 308 to analyze a main cause of an abnormal operating sound in more detail.
Thus, in a case in which the basis weight detection mode is selected for 20 consecutive sheets 2 on which the registration stop conveyance control is to be performed, the receive mode selection portion 301 of the present embodiment performs a control to switch the mode to the operating sound measurement mode. As a result, the operating sound measurement focusing on operating sounds other than those generated during the conveyance control can be performed at a constant frequency, thereby analyzing an abnormal operating sound in detail. A specific method thereof will be described later.
In the present embodiment, since the cassette tray 103 and the duplex conveying unit are added to the printer 203, there are three conveying routes for conveying the sheet 2 to the conveying path on which the receiver 71 is provided. Specifically, the three conveying routes include a route for conveying the sheet 2 from the cassette tray 101, a route for conveying the sheet 2 from the cassette tray 103, and a route for conveying the sheet 2 of which one side has been printed from the duplex conveying unit.
The cycle characteristic of properties of the sheets 2 described in the first embodiment will be discussed for each conveying path. First, different bundles of the sheets 2 may be stacked on the cassette tray 101 and the cassette tray 103, with independent cycles of properties of the sheets 2. Thus, in the present embodiment, the sheet feed count and the threshold value Tc obtained from the operating sound measurement timing table illustrated in
In addition, since a toner image has already been transferred and fixed onto the sheet 2 conveyed from the duplex conveying unit to the receiver 71, the basis weight of the sheet 2 has changed. Thus, the sheet 2 may be inappropriate for the receiver 71 to detect its basis weight. Therefore, in the present embodiment, all of the sheets 2 having been conveyed from the duplex conveying path 26 are conveyed in the operating sound detection mode. Note that, although the printer 203 of the present embodiment includes two tray units, even in a case in which three or more tray units included, the sheet feed count and the threshold value may be managed independently for each tray unit. As a result, as in the case in which two tray units are included, it is possible to perform operating sound measurement considering the cycle of the properties of the stacked sheets 2 for each cassette tray.
Next, in the present embodiment, a method in which the receive mode selection portion 301 performs the selection between the basis weight detection control and the operating sound detection control will be described.
In S901, the receive mode selection portion 301 determines whether a leading edge of a fed sheet 2 has reached the registration sensor 16 (Has a leading edge of a sheet reached the sensor?) on the basis of a detection result of the registration sensor 16. In a case in which the receive mode selection portion 301 determines that the leading edge of the sheet 2 has reached the registration sensor 16, the processing proceeds to S902, and in a case in which the receive mode selection portion 301 determines that the leading edge of the sheet 2 has not reached the registration sensor 16, the processing returns to S901.
In S902, the receive mode selection portion 301 acquires information regarding a feeding source of the sheet 2 from the image forming controller 200, and determines whether the sheet 2 has been conveyed from the duplex conveying path 26 of the duplex conveying unit (The sheet from the duplex conveying path?). In a case in which the receive mode selection portion 301 determines that the sheet 2 has been conveyed from the duplex conveying path 26 of the duplex conveying unit, the processing proceeds to S920 in order to perform operating sound detection. On the other hand, in a case in which the receive mode selection portion 301 determines that the sheet 2 has not been conveyed from the duplex conveying path 26 of the duplex conveying unit (the sheet 2 has fed from the cassette tray 101 or the cassette tray 103), the processing proceeds to S903.
In S903, the receive mode selection portion 301 determines whether the sheet 2 is a sheet having been fed from the cassette tray 101 (The sheet from the cassette tray 101?) on the basis of the information regarding the feeding source of the sheet 2 acquired from the image forming controller 200. In a case in which the receive mode selection portion 301 determines that the sheet 2 is a sheet having been fed from the cassette tray 101, the processing proceeds to S904. On the other hand, in a case in which the receive mode selection portion 301 determines that the sheet 2 is not a sheet having been fed from the cassette tray 101 (the sheet having been fed from the cassette tray 103), the processing proceeds to S908.
In S904, the receive mode selection portion 301 adds 1 to a value of the sheet feed count C1 indicating the number of the sheets 2 fed from the cassette tray 101 after the latest operating sound detection is performed. In S905, the receive mode selection portion 301 acquires a sheet type determination result M1 with respect to the sheet 2 of the cassette tray 101 from the image forming controller 200, and determines whether the type of the sheet 2 fed from the cassette tray 101 has been determined (Is there a sheet type determination result M1?). Here, the sheet type determination result M1 is a result of determining a sheet type of sheets in a sheet bundle accommodated in the cassette tray 101 on the basis of the result of detecting the property (here, basis weights) of the sheet 2 fed from the cassette tray 101, which is acquired from the basis weight detection controller 302 by the image forming condition switching portion 300. In a case in which the receive mode selection portion 301 determines that the type of the sheet 2 fed from the cassette tray 101 has been determined, the processing proceeds to S906, and in a case in which the receive mode selection portion 301 determines that the type of the sheet 2 has not been determined, the processing proceeds to S921. Note that the sheet type determination result with respect to the sheet 2 fed from the cassette tray 101 that the image forming controller 200 has is maintained until the operation of opening/closing the cassette tray 101 is performed after the basis weight of the sheet 2 is detected.
In S906, the receive mode selection portion 301 determines whether the sheet feed count C1 for the cassette tray 101 is equal to or larger than the threshold value Tc1 for the cassette tray 101 (Sheet feed count C1≥threshold value Tc1?). Here, the threshold value Tc1 is a value in the above-described table of
The processing of S908, S909, S910, and S911 are executed in a case in which the receive mode selection portion 301 determines that the sheet 2 is a sheet having been fed from the cassette tray 103 in the processing of S903. The processing of S908, S909, S910, and S911 is processing on the sheet 2 fed from the cassette tray 103, which corresponds to the processing of S904, S905, S906, and S907 on the sheet 2 fed from the cassette tray 101, respectively. The difference between the processing of S904 to S907 and the processing of S908 to S911 is as follows. That is, the difference is that while the sheet type determination result Ml, the sheet feed count C1, and the threshold value Tc1 for the cassette tray 101 are used in the processing of S904 to S907, a sheet type determination result M2, a sheet feed count C2, and a threshold value Tc2 for the cassette tray 103 are used in the processing of S908 to S911. Although the processing is separately performed for each cassette tray as described above, the processing of S908 to S911 corresponds to the processing of S904 to S907, respectively, with the same processing details. Thus, the description of the processing details will be omitted. In the processing of S904 to S907 and the processing of S908 to S911, controls are independently executed considering the cycles of properties of the cassette trays 101 and 103.
In S913, the receive mode selection portion 301 acquires registration stop conveyance control information from the image forming controller 200, and determines whether the sheet 2 is a target of the registration stop conveyance control (Registration stop conveyance control?) on the basis of the acquired registration stop conveyance control information. In a case in which the receive mode selection portion 301 determines that the sheet 2 is a target of the registration stop conveyance control, the processing proceeds to S914, and in a case in which the receive mode selection portion 301 determines that the sheet 2 is not a target of the registration stop conveyance control, the processing proceeds to S921. In S914, the receive mode selection portion 301 adds 1 to a value of the registration stop count indicating the number of times the basis weight detection mode has been continuously selected for the sheets 2 that are targets of the registration stop conveyance control. In S915, the receive mode selection portion 301 determines whether the registration stop count is equal to or larger than the threshold value Tcs (Registration stop count≥threshold value Tcs?). In a case in which the receive mode selection portion 301 determines that the registration stop count is equal to or larger than the threshold value Tcs, the processing proceeds to S916, and in a case in which the receive mode selection portion 301 determines that the registration stop count is smaller than the threshold value Tcs, the processing proceeds to S921. Note that the threshold value Tcs is a predetermined number of the sheets 2 to be fed, and the threshold value Tcs is set to 20 in the present embodiment. Accordingly, in the present embodiment, the operating sound measurement focusing on operating sounds other than those generated during the conveyance control can be performed at least once every 20 print jobs. In S916, the receive mode selection portion 301 resets the registration stop count to 0, and the processing proceeds to S920.
In S920, the receive mode selection portion 301 instructs the operating sound detection controller 305 to start measuring an operating sound of the printer 203, and then the processing proceeds to S922. In S921, the receive mode selection portion 301 selects the basis weight detection mode as the receive mode and instructs the basis weight detection controller 302 to start measuring the basis weight. Then, the processing proceeds to S922. In S922, the receive mode selection portion 301 acquires print job information from the image forming controller 200, and determines whether or not the print job has been completed (Has the print job been completed?) on the basis of the acquired information. In a case in which the receive mode selection portion 301 determines that the print job has not been completed, the processing returns to S901, and in a case in which the receive mode selection portion 301 determines that the print job has been completed, the processing ends.
In the present embodiment in which the printer 203 has the plurality of cassette trays 101 and 103 with the double-sided printing function, the method of determining the operating sound measurement timing considering the cycles of properties of the sheets 2 stacked on the cassette trays 101 and 103 has been described above. By considering the cycle characteristic of properties of the sheets 2 stacked on each cassette tray, it is possible to reduce deviations in results of detecting the basis weights of the sheets 2. Furthermore, by determining whether the sheet 2 has been fed from the duplex conveying path, it is possible to increase the operating sound measurement frequency.
In addition, in the present embodiment, the method of determining the operating sound measurement timing considering the influence of the sheet conveyance control on the operating sound measurement has also been described. By controlling the frequency of executing the operating sound measurement at the time of the registration stop conveyance control under which the sheet being conveyed is temporarily stopped, it is possible to increase the frequency of detecting abnormal operation sounds generated at places other than the sheet conveying units.
As described above, according to the present embodiment, it is possible to achieve both accurate detection of properties of recording materials and detection of operating sounds.
While the present disclosure has been described with reference to exemplary embodiments, it is to be understood that the disclosure is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2020-209698, filed Dec. 17, 2020, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2020-209698 | Dec 2020 | JP | national |