KR102219404B1 - Image forming apparatus and method for controlling the same - Google Patents

Abstract

The image forming apparatus includes: a condensation removal unit for executing a condensation removal process, which is a process for removing condensation inside the image forming apparatus; A receiving unit for receiving image data; And an image forming unit for forming an image on the media based on the image data received by the receiving unit, and when the receiving unit receives image data while the condensation removing unit is executing the condensation removing process, the image forming The unit does not form an image on the media, and the image forming unit forms an image on the media based on image data received while the condensation removing unit is executing the condensation removing processing after the condensation removing processing is finished.

Description

Image forming apparatus and its control method {IMAGE FORMING APPARATUS AND METHOD FOR CONTROLLING THE SAME}

The present invention relates to an image forming apparatus using an electrophotographic method.

In an electrophotographic image forming apparatus, when the environment in which the apparatus is installed, for example, a temperature around the apparatus fluctuates, condensation may form in the apparatus. Condensation in the device may cause an error during image formation, or may cause an image formed with low quality.

Japanese Unexamined Patent Application Publication No. 2000-209415 discloses a technique of outputting data received by FAX and storing it in a memory at the same time during the night, accompanied by a high risk of condensation. Japanese Patent Application Laid-Open No. 2005-39477 discloses a technology for heating a condensation preventing heater when the high-pressure output during image formation rapidly changes due to condensation.

Both of the apparatuses disclosed in Japanese Patent Application Laid-Open No. 2000-209415 and Japanese Patent Application Laid-open No. 2005-39477 perform image forming processing even under the risk of outputting a low-quality image due to occurrence of condensation. Therefore, when printing is performed under such a situation, the image quality of the output of image formation cannot be guaranteed.

The disclosed information aims at an image forming apparatus capable of guaranteeing the image quality of a printed image by limiting execution of an image forming operation under the risk of outputting a low-quality image due to occurrence of condensation in the image forming apparatus. Examples of such a situation include a situation in which the condensation removal process is being executed.

According to an aspect of the present invention, an image forming apparatus includes: a condensation removing unit for executing a condensation removing process, which is a process for removing condensation inside the image forming apparatus; A receiving unit for receiving image data; And an image forming unit for forming an image on the media based on the image data received by the receiving unit, and when the receiving unit receives image data while the condensation removing unit is executing the condensation removing process, the image forming The unit does not form an image on the media, and the image forming unit forms an image on the media based on image data received while the condensation removing unit is executing the condensation removing processing after the condensation removing processing is finished.

Further features of the present invention will become apparent from the following description of embodiments with reference to the accompanying drawings.

1 is a block diagram showing an example of a hardware configuration of a multi-function peripheral (MFP) according to the first embodiment.
2 is a view showing an example of the appearance of an optical scanning system in an image forming unit.
3 is a block diagram showing an example of a software configuration of an MFP according to the first embodiment.
4 is a flowchart showing an example of a condensation determination process and a condensation removal process according to the first embodiment.
5 is a flowchart showing an example of a facsimile (FAX) receiving process according to the first embodiment.
6 is a flowchart showing an example of processing for printing and storing a FAX received image according to the first embodiment.
7 is a flowchart showing an example of a print process of a FAX received image according to the first embodiment.
Fig. 8 is a flowchart showing an example of print processing of a personal computer (PC) print job according to the first embodiment.
Fig. 9 is a flowchart showing an example of control of recording and storage of FAX received images and confirmation processing of a condensation removal processing flag according to the second embodiment.
Fig. 10 is a flowchart showing an example of condensation determination processing according to the third embodiment.
11 is a flowchart showing an example of the start process of the condensation determination process according to the third embodiment.
12 is a flowchart showing an example of processing for printing and storing a FAX received image according to the fourth embodiment.

Hereinafter, embodiments will be described with reference to the drawings. The examples are not intended to limit the scope of the invention described in the claims. Not all of the combinations of features described in that embodiment are essential to the solution provided by the present invention.

The first embodiment will be described.

1 is a block diagram showing an example of a hardware configuration of a multifunction peripheral (MFP) according to the first embodiment.

As shown in FIG. 1, the MFP 10 includes a central processing unit (CP) 101, a read-only memory (ROM) 102, a random access memory (RAM) 103, a display controller 104, and A display portion 105, an operation controller 106, and an operation portion 107 are provided. The MFP 10 further includes a built-in multimedia card (EMMC) host controller 108, an eMMC 109, a reading controller 110, a reading unit 111, a recording controller 112, and a recording unit 113. . The MFP 10 further includes a general-purpose serial bus (USB) host controller 114, a modem 115, a network control unit (NCU) 116, and a network interface card (NIC) 117.

The CPU 101 controls each device connected to the system bus 118. When the CPU 101 receives power, the CPU 101 executes the boot program stored in the ROM 102. The CPU 101 executes the boot program, loads the main program stored in the eMMC 109, which is a storage, into the RAM 103, and jumps to the head of the loaded main program. The RAM 103 not only functions as an area into which the main program is loaded, but also functions as a work area of the main program.

The display controller 104 controls drawing on the display unit 105. The display unit 105 is a liquid crystal display (LCD) capable of displaying a character string of 28 characters x 7 lines, ruled lines, and scroll bars. The operation controller 106 accepts an operation input through the operation unit 107 of the MFP 10. The operation unit 107 includes a numeric keypad, a cursor key, and a one-touch key.

The reading unit 111 reads a manuscript. The reading unit 111 may be provided with a document transfer device. The reading unit 111 provided with the document transfer device can automatically read a plurality of documents. The reading unit 111 is connected to the reading controller 110. The CPU 101 transmits and receives data to and from the reading unit 111 via the reading controller 110.

The recording unit 113 performs printing (image formation) on a sheet based on an electrophotographic method. The recording unit 113 is connected to the recording controller 112. The CPU 101 transmits and receives data to and from the recording unit 113 via the recording controller 112.

The USB host controller 114 controls the USB protocol and mediates access to USB devices such as a USB memory (not shown).

The modem 115 modulates/demodulates signals required for facsimile (FAX) communication. The modem 115 is connected to the NCTV 116. The signal modulated by the modem 115 is transmitted to a public line network (PSTN) through the NCTV 116.

The NIC 117 transmits and receives data to and from a mail server, a file server, a client terminal, and the like through a local area network (LAN). The LAN according to the first embodiment may be constructed by Ethernet (registered trademark), or may be a wireless network supporting IEE 802.11.

The MFP 10 according to the present embodiment includes the EMMC 109 as a storage. The CPU 101 accesses the eMMC 109 via the eMMC host controller 108. Instead of the EMMC 109, a solid state drive (SSD) or a hard disk may be used.

The recording unit 113 includes a CPU 200, an ROM 201, an ROM 202, and a serial interface 203. The recording unit 113 further includes an I/O 204, an image forming unit 205, a paper conveying system unit 206, and a temperature sensor 207.

Upon receiving the power, the CPU 200 executes the recording unit control program stored in the ROM 201. The RAM 202 functions as a work area of the recording unit control program. The CPU 200 receives various commands issued by the main program of the MFP 10 via the serial interface 203, and according to the received various commands, the I/O 204 connected to the system bus 208 ) To control the image forming unit 205 or the paper conveying system unit 206. Further, the CPU 200 can obtain a temperature measurement result from the temperature sensor 207 via the I/O 204.

The image forming unit 205 forms an image on the sheet conveyed by the paper conveying system unit 206 using an electrophotographic method. The temperature sensor 207 is disposed in the MFP 10, for example, near the image forming unit 205, and measures the temperature in the vicinity of the image forming unit 205 as the environmental temperature of the MFP 10. The fan 209 exhausts air in the MFP 10, creates a flow of air in the MFP 10, and can reduce the temperature difference between the inside and the outside of the MFP 10.

2 is a diagram showing an example of the appearance of an optical scanning system in the image forming unit 205. The laser driving system circuit 226 is a circuit for supplying a driving current to the semiconductor laser 214 which is a light emitting element. The semiconductor laser 214 emits a laser beam at a light emission amount corresponding to a driving current. The laser beam emitted from the semiconductor laser 214 is collimated by a collimator lens 216 as a collimating beam. Then, this beam is reflected so as to be scanned by the f? lens 220 by the rotating polygon mirror 218. By the f? lens 220, the scanned laser beam is imaged on the surface of the photosensitive drum 210 rotating around its axis so that the photosensitive drum 210 is scanned horizontally by this beam.

The reflection mirror 222 is provided at a position corresponding to the scanning position on one end side of the photosensitive drum 210, and a beam detection (BD) element (synchronous signal detection element) 224 for the laser beam emitted at the scanning start position It reflects towards Based on the output of the BD detection element 224, the timing at which laser beam scanning starts is determined.

When condensation occurs on the photosensitive drum 210, image formation by the electrophotographic method is inhibited, and an image cannot be properly formed in some cases. In this case, the quality of the image formed on the sheet cannot be maintained. When condensation occurs in the BD detection element 224, the BD element 224 may not be able to detect the laser beam. In this case, the timing of starting the scanning of the laser beam cannot be determined, and the MFP 10 enters an error state.

Fig. 3 is a block diagram showing an example of a software configuration of the MFP 10 according to the first embodiment. The constituent elements shown by solid lines in Fig. 3 are software modules realized by the CPU 101 executing the main program loaded in the RAM 103 as the above-described boot program.

Modules implemented as a main program to be described later are managed and controlled by an operating system (OS) 301. The device driver 308 is combined with the OS 301. The device driver 308 mediates the exchange with hardware devices such as the recording controller 112 and the modem 115.

The user interface (UI) 302 provides various types of information to the user via the display unit 105 and the operation unit 107, and accepts various instructions from the user.

The job controller 303 accepts a job such as copy, print, or fax, and controls execution of the received job.

The storage unit 306 is a software module that physically stores and manages data such as images and user settings transmitted or received by FAX in the EMMC 109.

When the job controller 303 accepts the FAX job, the scanning unit 307 receives the job request and controls the reading unit 111 to scan the manuscript. Then, the scanned FAX image data is stored in the storage unit 306. The FAX image data stored in the storage unit 306 is read out by the FAX unit 304, and is transmitted by FAX to the other party via the modem 115 and the NC 116. The FAX unit 304 acquires the image data received by fax from the other party via the modem 115 and the NCTV 116, and stores the image data in the storage unit 306.

The print unit 305 transmits various predetermined commands to the recording unit 113 via the recording controller 112, receives the state of the recording unit 113, and controls the operation of the recording unit 113. For example, in the case of printing a fax received image, after sending a print command to the recording unit 113, the print unit 305 reads the image file stored in the storage unit 306, and image data in the image file Is transferred to the recording unit 113.

The MFP 10 includes a virtual machine (VM))/framework (FW) unit 309. The extended application unit 310 is configured with a specific program described in a script language.

4 is a flowchart showing an example of operations of the condensation determination process and the condensation removal process executed by the recording unit 113 according to the first embodiment. The processing in Fig. 4 may be executed, for example, when the MFP 10 is set to operate in the condensation removal mode by the user. For example, the user can turn on/off the condensation removal process via the operation unit 107. The contents of the user setting are stored in the eMMC 109 or the like. The flowchart shown in Fig. 4 is executed when the condensation removal process is on.

The condensation determination processing from steps S4-001 to S4-008 is part of the recording unit control program described with reference to Fig. 2, and is automatically executed when the CPU 200 of the recording unit 113 is supplied with power. Alternatively, by executing the program by the CPU 101, the condensation determination processing from steps S4-001 to S4-008 can be executed on the CPU 200.

First, in step S4-001, the CPU 200 acquires the measurement result of the environmental temperature t(i) of the MFP 10 from the temperature sensor 207 shown in FIG. 2. In this embodiment, the environmental temperature is, for example, the temperature in the MFP 10. Next, in step S4-002, the CPU 200 determines whether or not the condensation removal process is being executed. If the condensation removal processing (described later) is not being executed (NO in step S4-002), the process proceeds to step S4-003. On the other hand, if the condensation removal process is being executed (YES in step S4-002), the process proceeds to step S4-006.

In step S4-003, the CPU 200 determines whether or not the environmental temperature t(i-1) measured at a point preceding the current point by a predetermined time S1 to be described later is equal to or less than the predetermined temperature T1. The environmental temperature t(i-1) is stored in the RAM 202, and in step S4-003, the environmental temperature t(i-1) is read from the RAM 202. If the environmental temperature t(i-1) is equal to or less than the predetermined temperature T1 (YES in step S4-003), the process proceeds to step S4-004. On the other hand, if the environmental temperature t(i-1) is higher than the predetermined temperature T1 (NO in step S4-003), the process proceeds to step S4-006. Even when the measured environmental temperature at a point preceding the current point by a predetermined time S1 cannot be obtained, the process proceeds from step S4-003 to step S4-006. An example of such a case includes the timing immediately after the MFP 10 is started.

In step S4-004, the CPU 200 has a difference between the environmental temperature t(i) acquired in step S4-001 and the environmental temperature t(i-1) measured at a point preceding the current point by a predetermined time S1. , It is determined whether or not it is greater than a predetermined value D. If the difference is greater than the predetermined value D (YES in step S4-004), the process proceeds to step S4-005. On the other hand, if the difference is not greater than the predetermined value D (NO in step S4-004), the process proceeds to step S4-006.

Therefore, in the processing of step S4-005, it is determined that the environmental temperature t(i-1) is equal to or less than the predetermined temperature T1 in step S4-003, and the difference t(i)-t(i-1) in step S4-004 When it is determined that this is greater than the predetermined value D, it is executed. This means that the temperature in the MFP 10 has risen under a relatively low temperature accompanying a high risk of condensation, and condensation may have occurred. In step S4-005, the CPU 200 starts the condensation removal process, and proceeds to the process of step S4-006.

In step S4-006, the CPU 200 stores the environmental temperature t(i) measured in step S4-001 in the RAM 202. Then, in step S4-007, the CPU 200 waits until the predetermined time S1 has elapsed. When the predetermined time S1 has elapsed (YES in step S4-007), the process proceeds to step S4-008. In step S4-008, the CPU 200 increments i by one, and returns to the processing of step S4-001. Accordingly, the environmental temperature t(i) is measured once every predetermined time S1 by steps S4-007 and S4-008.

The processing performed from step S4-010 to step S4-014 is a condensation removal processing, and is started by the processing of step S4-005.

First, in step S4-010, the CPU 200 sends a notification indicating that the condensation removal process has started (that is, that condensation may have occurred in the MFP 10), via the serial interface 203. It is issued to the CPU 101 (hereinafter, this notification is referred to as a condensation removal processing notification). When the main program executed by the CPU 101 recognizes receipt of this condensation removal processing notification, the condensation removal processing flag in the RAM 202 is turned on. The condensation removal processing flag is turned on when the condensation removal processing is being executed in the recording unit 113.

Then, in step S4-011, the CPU 200 rotates the fan 209 included in the MFP 10 at full speed. This processing is performed to facilitate reduction of the difference between the temperature inside the MFP 10 and the temperature outside the MFP 10, thereby removing condensation generated inside the MFP 10 or recovering from a state in which condensation is likely to occur. The condensation removal process according to the first embodiment is executed by rotation of the fan 209 at full speed. Alternatively, the fan 209 may rotate at a speed other than full speed as long as the effect of removing condensation can be obtained.

In step S4-012, the CPU 200 waits until the predetermined time S2 elapses while rotating the fan 209. The predetermined time S2 corresponds to a period of full speed rotation of the fan 209 expected to remove condensation inside the MFP 10.

When the predetermined time S2 has elapsed (YES in step S4-012), the process proceeds to step S4-013. In step S4-013, the CPU 200 stops the fan 209. When the fan 209 rotates at a predetermined speed before executing the processing in step S4-011, the CPU 200 rotates the predetermined speed without stopping the fan in step S4-013.

In step S4-014, the CPU 200 issues a notification indicating that the condensation removal process has ended (that is, that the condensation in the MFP 10 has been removed) to the CPU 101 in the same manner as in step S4-010. do. After that, the condensation removal process is ended.

Upon receiving a notification indicating that the condensation removal processing has ended, the CPU 101 turns off the condensation removal processing flag.

5 is a flowchart showing an example of the FAX reception process according to the first embodiment. The steps in the flowchart shown in Fig. 5 are realized through execution of the main program loaded in the CPU 101 into the RAM 103. More specifically, this flowchart is executed by a part of the program constituting the FAX unit 304. When the fax is received via the NC 116 and negotiation of the fax reception procedure is completed, the fax reception process starts.

In step S5-001, the CPU 101 waits until reception of the fax image of one page is completed. When the reception of the FAX image of page 1 is completed (YES in step S5-001), the process proceeds to step S5-002. In step S5-002, the CPU 101 converts the received FAX image into a predetermined image format, and is stored as an image file of one page in the EMMC 109 by the storage unit 306.

Then, in step S5-003, the CPU 101 determines whether or not a signal indicating that a subsequent page exists in the order of FAX reception has been received. If there is a subsequent page (YES in step S5-003), the process returns to step S5-001. If there is no subsequent page (NO in step S5-003), the process proceeds to step S5-004. In step S5-004, the CPU 101 ends the FAX reception process.

6 is a flowchart showing an example of processing for printing and storing a FAX received image according to the first embodiment. The steps in the flowchart shown in Fig. 6 are realized through execution of the main program loaded into the RAM 103 by the CPU 101. More specifically, this flowchart is executed by a part of the program constituting the print unit 305. This flowchart automatically starts after the main program initialization process.

In step S6-001, the CPU 101 waits for one or more FAX reception jobs generated as a result of executing the FAX reception processing according to the flowchart shown in Fig. 5. More specifically, the CPU 101 waits until the storage unit 306 stores the FAX received image. When the fax received job image is stored (YES in step S6-001), the process proceeds to step S6-002.

In step S6-002, the CPU 101 determines whether or not the condensation removal processing flag is on. If the condensation removal processing flag is off (NO in step S6-002), the process proceeds to step S6-003. On the other hand, if the condensation removal processing flag is on (YES in step S6-002), the process proceeds to step S6-005.

In step S6-003, the CPU 101 determines whether or not the recording unit 113 is in a printable state. For example, when there is no sheet or toner, or when a paper jam occurs during printing, it is determined that the recording unit 113 is in a non-printable state (not printable). If the recording unit 113 is not in a print-unable state (NO in step S6-003), the process proceeds to step S6-004. On the other hand, if the recording unit 113 is in a print-unable state (YES in step S6-003), the process proceeds to step S6-005.

In step S6-004, a FAX received image is printed as described in detail below. After that, the process returns to step S6-001.

In step S6-005, the CPU 101 requests the UI 302 to display a message indicating that the FAX received image is not printed and stored in the memory (EMMC 109).

If the condensation removal processing flag is turned on in step S6-002, it is assumed that condensation has occurred inside the recording unit 113. If the FAX image performed in such a case is printed, there is a possibility that printing may be wrong or an image of low image quality may be printed. Therefore, under such conditions, the FAX image is stored in the memory without printing. The condensation removal processing ends when the predetermined time S2 has elapsed, and the condensation removal processing flag is thus turned off, and the determination result in step S6-002 is NO. Thus, the FAX image stored in the memory can be printed in step S6-004.

Fig. 7 is a flowchart showing an example of a print process of a FAX received image according to the first embodiment. The steps in the flowchart shown in Fig. 7 are realized through execution of the main program loaded into the RAM 103 by the CPU 101. More specifically, this flowchart is executed by a part of the program constituting the print unit 305.

In step S7-001, the CPU 101 determines whether or not the condensation removal processing flag is on. If the condensation removal processing flag is off (NO in step S7-001), the process proceeds to step S7-002. If the condensation removal processing flag is on (YES in step S7-001), the processing of this flowchart is ended.

In step S7-002, the CPU 101 determines whether or not the recording unit 113 is in a printable state. If the recording section 113 is not in a print-unable state (NO in step S7-002), the process proceeds to step S7-003. On the other hand, if the recording unit 113 is in a print-unable state (YES in step S7-002), the process of this flowchart is ended.

In step S7-003, the CPU 101 determines whether or not image data to be printed is stored in the EMMC 109. When the image data to be printed is stored (YES in step S7-003), the process proceeds to step S7-004. On the other hand, if the image data to be printed is not saved (NO in step S7-003), the process proceeds to step S7-007.

In step S7-004, the CPU 101 prints image data to be printed. More specifically, the CPU 101 reads image data from the EMMC 109 and issues a command related to printing and the read image data to the recording unit 113 via the recording controller 112, The image is printed on the recording unit 113.

In step S7-005, the CPU 101 determines whether or not the printing in step S7-004 was successful. If the printing was successful (YES in step S7-005), the process proceeds to step S7-006. In step S7-006, the CPU 101 erases the printed image data from the EMMC 109. On the other hand, if the printing has failed (NO in step S7-005), the process returns to step S7-001, and the CPU 101 attempts to print the image data again.

If the CPU 101 determines that image data to be printed is not stored in step S7-003 (NO in step S7-003), the process proceeds to step S7-007. In step S7-007, the CPU 101 erases the management information of the FAX reception job from the EMMC 109, and ends the FAX reception job print processing.

Fig. 8 is a flowchart showing an example of print processing of a personal computer (PC) print job according to the first embodiment. The steps in the flowchart shown in Fig. 8 are realized through execution of the main program loaded into the RAM 103 by the CPU 101. More specifically, this flowchart is executed by a part of the program constituting the print unit 305.

The PC print job refers to receiving print data transmitted from the PC, which is an example of an information processing device outside the MFP 10, through the PCI 117, and printing based on the received print data.

The MFP 10 according to the first embodiment may set in advance whether or not to allow the execution of printing based on the PC print job while the condensation removal processing in the recording unit 113 is being executed. This setting is called a print priority setting. The print priority setting is turned on and off by the instruction of the user or the administrator of the MFP 10 via the operation unit 107, and the result setting is stored in the EMMC 109. Even when the print priority setting is on, printing of the FAX received image is not permitted while the condensation removal process is being executed. Therefore, the print priority setting is not related to the processing in the flowchart shown in Fig. 7 described above.

First, in step S8-001, the CPU 101 checks whether the print priority setting is on or off. If the print priority setting is off (NO in step S8-001), the process proceeds to step S8-002. On the other hand, if the print priority setting is on (YES in step S8-001), the process of step S8-002 is skipped and the process proceeds to step S8-003. Therefore, when the print priority setting is on, printing based on the PC print job is executed even when the condensation removal processing flag is on. When the condensation removal processing flag is on, the recording unit 113 executes the condensation removal processing. However, this does not necessarily mean that condensation has occurred in the MFP 10. Even when printing based on the PC print job becomes a low-quality image due to condensation in the MFP 10, the user can issue a print instruction from the PC again. Therefore, a user who wants to avoid stopping printing may turn on the print priority setting.

In step S8-002, the CPU 101 determines whether or not the condensation removal processing flag is on. If the condensation removal processing flag is off (NO in step S8-002), the process proceeds to step S8-003. On the other hand, if the condensation removal processing flag is on (YES in step S8-002), the process proceeds to step S8-009.

In step S8-003, the CPU 101 determines whether or not the recording unit 113 is in a printable state. If the recording unit 113 is not in a print-inhibited state (NO in step S8-003), the process proceeds to step S8-004. On the other hand, if the recording unit 113 is in the print-inhibited state (YES in step S8-003), the process proceeds to step S8-009.

In step S8-004, the CPU 101 prints the image data of one page to be printed. Then, in step S8-005, the CPU 101 determines whether or not the printing in step S8-004 has been successful. If the printing is successful (YES in step S8-005), the process proceeds to step S8-006. On the other hand, if the printing has failed (NO in step S8-005), the process returns to step S8-001.

In step S8-006, the CPU 101 erases the image data of the successfully printed page from the EMMC 109.

In step S8-007, the CPU 101 determines whether or not there is image data of the next page to be printed. If the next page of image data to be printed exists (YES in step S8-007), the process returns to step S8-001 to print the next page of image data. On the other hand, if there is no image data of the next page to be printed (NO in step S8-007), the process proceeds to step S8-008.

In step S8-008, the CPU 101 erases the management information of the PC print job, in which all the pages have been successfully printed, from the EMMC 109. Then, the print processing of the PC print job is ended.

In step S8-009, the CPU 101 requests the UI 302 to display a message on the display unit 105 indicating that printing of the PC print job is being held due to condensation or because printing is impossible.

In the above first embodiment, when the MFP 10 is executing the condensation removal process, there is a high possibility that condensation occurs in the MFP 10. Therefore, while the condensation removal process is being executed, the image forming process based on the FAX reception is restricted, and the received FAX image data is saved. As a result, it is prevented from meaninglessly performing printing that will only be of low quality. At the same time, loss of image data received via fax can be prevented while condensation is occurring.

In addition, the MFP 10 can perform the same control as the FAX reception job also on the PC print job.

The processing of the flowchart shown in Fig. 8 may also be applied to the copy processing in which the recording unit 113 prints the image on the original read by the reading unit 111.

In the first embodiment, the same processing is performed when the condensation removal processing flag is on and when printing is not possible. Further, the processing to be executed may be different between the case where the condensation removal processing flag is on and the case where printing is not possible.

Fig. 9 is a flowchart showing an example of control of printing and storage of a fax received image and confirmation processing of a condensation removal processing flag according to the second embodiment. The hardware configuration and software configuration of the MFP 10 according to the second embodiment are the same as those shown in FIGS. 1 to 3. The condensation determination processing and the condensation removal processing executed in the recording unit 113 are as shown in FIG. 4.

The steps of the flowchart shown in Fig. 9 are realized through execution of the main program loaded into the RAM 103 by the CPU 101.

In the flowchart shown in Fig. 9, steps S9-001, S9-003, S9-004, and S9-005 are, respectively, steps S6-001, S6-003, S6-004 in the flowchart shown in Fig. 6, Same as S6-005.

The MFP 10 according to the second embodiment may store a setting (forced memory reception setting) 9000 for not performing printing by storing a FAX received image in a memory in the EMMC 109. In step S9-002, the CPU 101 checks whether the forced memory reception setting 9000 is on. If the forced memory reception setting (9000) is on, the process proceeds to step S9-006. On the other hand, if the forced memory reception setting (9000) is off, the process proceeds to step S9-003.

In step S9-006, the CPU 101 stores the FAX received image in the EMMC 109 without printing it, and displays a message indicating that the image has been stored in the memory on the display unit 105, so that the UI 302 ). Then, the process returns to step S9-001.

The processing for confirming the condensation removal processing flag consists of steps S9-007 to S9-012.

First, in step S9-007, the CPU 101 checks whether the condensation removal processing flag is on. If the condensation removal processing flag is on (YES in step S9-007), the process proceeds to step S9-008. On the other hand, if the condensation removal processing flag is off (NO in step S9-007), the process proceeds to step S9-011.

In step S9-008, the CPU 101 temporarily stores the current setting value of the forced memory reception setting 9000 in a predetermined area in the EMMC 109.

Then, in step S9-009, the CPU 101 rewrites the set value of the forced memory reception setting 9000 to a value indicating "remember".

Then, in step S9-010, the CPU 101 requests the UI 302 to make the setting change impossible via the operation unit 107. In response to the request, the UI 302 grays out the menu display for setting the compulsory memory reception setting 9000 so that the user cannot change the setting.

In step S9-011, the CPU 101 returns the set value of the forced memory reception setting 9000 to the set value temporarily stored in step S9-008.

Then, in step S9-012, the CPU 101 requests the UI 302 to allow the setting change on the operation unit 107 to be permitted.

As described above, according to the second embodiment, the same effects as those of the first embodiment can be obtained even when the condensation removal flag is not considered to be the same as the print impossible state.

Convenience can be improved by forcibly allowing the FAX received image received by the memory to be viewed in a web browser such as a PC connected via the display unit 105 or the NIC 117.

In the example described in the third embodiment, the MFP 10, which has transitioned to the power saving mode, returns to the normal power mode and measures the environmental temperature when the timing of measuring the environmental temperature comes. In the power saving mode, power consumption of the entire apparatus is lowered compared to the normal power mode by stopping the power supply to the recording controller 112 and the recording unit 113 at least. In the example described in this embodiment, even in the power saving mode, since the CPU 101 receives power supply, the recording unit 113 can be controlled, and condensation determination processing can be executed. In addition, the power supply to the CPU 101 may be stopped in the power saving mode. In such a configuration, the timer may periodically raise the CPU 101 (ie, transition to a power-supplied state), and perform the following processing.

In the power saving mode, since the supply of power to the recording unit 113 is stopped, the temperature sensor 207 in the recording unit 113 cannot measure its environmental temperature. Accordingly, the CPU 101, which can operate in the power saving mode, controls the recording controller 112 and the recording section 113 to return the recording section 113 from the power saving mode at a predetermined timing. The returned recording unit 113 executes the condensation determination process described with reference to FIG. 4. When the result of the condensation determination process indicates that the condensation removal process needs to be executed (YES in step S4-004), the condensation removal process is executed. When it is determined that the processing does not need to be executed (NO to step S4-004), the recording unit 113 returns to the power saving mode.

Condensation determination processing according to the present embodiment will be described with reference to FIG. 10. The process shown in Fig. 10 is a process that is executed by the recording unit 113 by the CPU 101 executing the program stored in the ROM 102.

In step S1001, the CPU 101 determines whether or not the condensation removal processing flag is on. If the condensation removal processing flag is off (NO in step S1001), the processing in step S1001 is repeated. On the other hand, if the condensation removal processing flag is on (YES in step S1001), the process proceeds to step S1002. In step S1002, the CPU 101 determines whether the MFP 10 is in the sleep mode. When the MFP 10 is not in the sleep mode (NO in step S1002), the process returns to step S1001. When the MFP 10 is in the sleep mode (YES in step S1002), the process returns to step S1003. In step S1003, the CPU 101 determines whether the sleep mode is maintained for a predetermined time S3. The predetermined time S3 according to the present embodiment may be longer than the predetermined time S1 shown in FIG. 4, for example. If the sleep mode has not been maintained for the predetermined time S3 (NO in step S1003), the process returns to step S1001. On the other hand, if the sleep mode is maintained for a predetermined time S3 (YES in step S1003), the process proceeds to step S1004. In step S1004, the CPU 101 returns the recording unit 113 from the sleep mode. Upon returning from the sleep mode, the recording unit 113 executes the condensation determination process and the condensation removal process described with reference to FIG. 4.

When the condensation determination processing is executed in the recording unit 113, in step S1005, the CPU 101 receives a notification from the recording unit 113 indicating the result of the condensation determination processing. Then, in step S1006, the CPU 101 determines whether transition to the sleep mode is possible based on the received notification. The CPU 101 according to the present embodiment determines that the transition to the sleep mode is possible when the sleep mode transition condition at least including reception of a notification indicating that condensation does not occur from the recording unit 113 is satisfied. . On the other hand, when the condensation removal process described above with reference to Fig. 4 is executed due to the occurrence of condensation, the CPU 101 determines that the transition to the sleep mode is not possible. When the CPU 101 determines that the transition to the sleep mode is not possible (NO in step S1006), it returns to the process of step S1001. When the CPU 101 determines that the transition to the sleep mode is possible (YES in step S1006), the process proceeds to step S1007. In step S1007, the CPU 101 shifts the MFP 10 to the sleep mode, and then returns to the processing of step S1001.

In the example described in this embodiment, the result of the condensation determination processing is received in step S1005. In addition, this processing may be omitted. As a result of the condensation determination processing, when it is determined that the condensation removal processing is necessary and executed, an operation such as rotation of the fan 209 starts. Accordingly, in step S1006, the CPU 101 can determine that the transition to the sleep mode is not possible. When a predetermined time elapses without an operation such as rotation of the fan 209, the CPU 101 determines that the transition to the sleep mode is possible in step S1006, and puts the MFP 10 in the sleep mode in step S1007. You may transfer to.

Next, the processing executed by the CPU 200 when the recording unit 113 returns from the sleep mode will be described with reference to FIG. 11. In step S1101, the CPU 200 determines whether the recording unit 113 has returned from the sleep mode. When the recording unit 113 returns from the sleep mode (YES in step S1101), the process proceeds to step S1102. In step S1102, the CPU 200 determines whether the condensation removal processing flag is on. When the condensation removal processing flag is off (NO in step S1102), the processing ends. On the other hand, when the condensation removal processing flag is on (YES in step S1102), the process proceeds to step S1103. In step S1103, the CPU 200 executes the condensation determination process described with reference to FIG. 4. Then, in step S1104, the CPU 200 notifies the CPU 101 of the result of the condensation determination process.

According to the present embodiment, even when the MFP 10 is in the sleep mode, the environmental temperature of the MFP 10 is periodically measured, and when it is determined that condensation has occurred, the condensation removal process can be started.

In the example described in the first and second embodiments, in the FAX reception print and storage control, when condensation occurs, forced memory reception is performed. In the example described in this fourth embodiment, storing the FAX received image in the memory without printing it is not based on the compulsory memory reception setting. Instead, the FAX received image is stored in the memory without being printed when the MFP 10 determines that it is in a print impossible state including a state in which the condensation removal process is being executed. In this embodiment, the CPU 101 executes the processing shown in FIG. 12 instead of the processing shown in FIGS. 6 and 9. Other configurations and processes are the same as those shown in the first embodiment or the second embodiment, and thus description thereof is omitted.

The processing in FIG. 12 is realized through execution of a program stored in the ROM 102 by the CPU 101. In step S1201, the CPU 101 determines whether or not the FAX received image has been stored. If the FAX received image is not stored (NO in step S1201), the process of step S1201 is repeated. On the other hand, when the FAX received image is stored (YES in step S1201), the process proceeds to step S1202. In step S1202, the CPU 101 determines whether the MFP 10 is in a print impossible state. The printing impossible state according to the present embodiment includes a state in which the condensation removal process is being processed while the fan 209 rotates. If the MFP 10 is not in the print impossible state (NO in step S1202), the process proceeds to step S1203. In step S1203, the CPU 101 prints a FAX received image. Details of the print processing of the FAX received image are the same as those described in Fig. 5, and thus the description thereof will be omitted. When the MFP 10 is in a print-inhibited state (YES in step S1202), the process proceeds to step S1204. In step S1204, the CPU 101 performs control so that the received image is stored without being printed in the memory. Then, in step S1205, the CPU 101 requests the display unit 105 to display a message indicating that the image is stored without being printed. Then, the process returns to step S1201.

Also by the above processing, it is possible to prevent printing of the FAX received image when the condensation removal process is being executed due to the occurrence of condensation. Therefore, printing that will only deteriorate image quality is prevented from being performed meaninglessly. At the same time, it prevents loss of image data received via fax while condensation is occurring. Also, as in the first and second embodiments, the above-described effect can be obtained without using management including checking whether the forced memory reception setting flag is on or off.

In the configurations according to the first and second embodiments, if the condensation removal processing flag is on, the FAX received image is not printed. Further, in the configuration described below, it is possible to execute the condensation removal process without the risk of losing the received data while the condensation is occurring, without suspending printing. More specifically, step S6-002 in Fig. 6 is deleted, and step S7-001 in Fig. 7 is moved between steps S7-005 and S7-006, and before step S7-007. Further, the process of step S7-003 may be changed to a process of determining whether or not a page to be printed remains. Therefore, even when the condensation removal processing flag is on, the print processing of the fax received image is executed. Even with this configuration, it is possible to execute the condensation removal process without the risk of losing received data while condensation is occurring. Nevertheless, this configuration is not without the risk of printing a low-quality image.

In the recording unit condensation determination processing shown in Fig. 4 according to the first embodiment, it is determined whether condensation is occurring based on the absolute temperature obtained from the temperature sensor 207 and the amount of change per unit time. The condensation determination process is not limited to this. For example, the recording unit 113 shown in FIG. 2 may further include a humidity sensor. A more accurate condensation determination process can be made by estimation based on the measurement results of the temperature sensor 207 and the humidity sensor. Alternatively, the presence or absence of condensation may be determined based on the charged state of the photosensitive drum 210.

In the configuration according to the first and second embodiments, the condensation determination process is executed in any environment. In general, condensation occurs in a confined environment at low temperatures. Therefore, for example, the user's environment may be selected through the navigation when the MFP 10 is installed by the main program, and the recording unit may execute the condensation determination process only when the MFP 10 is used in a low temperature area. good.

The dew condensation removal processing according to each of the above-described embodiments is performed by rotating the fan 209 provided in the image forming unit 205 of the recording unit 113 at full speed. However, the condensation removal process is not limited to this. For example, the image forming unit 205 may include a condensation preventing heater, or may remove condensation by heating this heater for a predetermined time.

Other Examples

In addition, the embodiment(s) of the present invention read computer-executable instructions (e.g., one or more programs) recorded on a storage medium (more completely, also referred to as a'non-transitory computer-readable storage medium'). And/or one or more circuits for performing one or more functions of the above-described embodiment(s) and/or one or more circuits (eg, ASIC) for performing one or more functions of the above-described embodiment(s). Implemented by a computer having a system or device, and performing one or more functions of the embodiment(s), for example by reading and executing the computer-executable instructions from the storage medium, and And/or by controlling the one or more circuits that perform one or more functions of the above-described embodiment(s), by means of a method performed by the computer with the system or the device. The computer may include one or more processors (for example, a central processing unit (CPU), a microprocessing unit (MPU)), and a separate computer or a separate processor in order to read and execute computer executable instructions. You may have a network. The computer executable instruction may be provided to the computer from, for example, a network or the storage medium. The storage medium may be, for example, a hard disk, random access memory (RAM), read-only memory (ROM), storage of a distributed computing system, optical disk (compact disk (CD), digital multifunction disk (DVD)), or Blu-ray. Disk (BD) ^TM, etc.), flash memory devices, memory cards, and the like may be provided.

While the present invention has been described with reference to embodiments, it will be appreciated that the invention is not limited to the disclosed embodiments. The scope of the claims below is to be interpreted broadly to include all modifications and equivalent structures and functions.

Claims (14)

As an image forming apparatus,
A condensation removing unit that executes a condensation removing process which is a process for removing condensation inside the image forming apparatus;
A receiving unit for receiving image data; And
An image forming unit for forming an image on the media based on the image data received by the receiving unit,
When the receiving unit receives image data while the condensation removing unit is executing the condensation removing processing, the image forming unit does not form an image on the media, and after the condensation removing processing is finished, the condensation removing unit An image forming apparatus, wherein the image forming unit forms an image on a medium based on image data received while executing a removal process.
The method of claim 1,
And a storage unit for storing image data received while the condensation removing unit is executing the condensation removing process.
The method of claim 1,
The image forming unit, at the end of the condensation removing processing executed by the condensation removing unit, forms an image on the media based on image data received while the condensation removing unit is executing the condensation removing processing. Device.
The method of claim 2,
The image forming unit, wherein the image forming unit forms an image on the media based on the image data stored in the storage unit after the condensation removal processing is finished.
The method of claim 1,
The image forming apparatus, wherein the receiving unit receives facsimile image data.
The method of claim 5,
When the receiving unit receives different types of image data while the condensation removing unit is executing the condensation removing processing, the image forming unit may be configured to receive the different types of image data while the condensation removing unit is performing the condensation removing processing. An image forming apparatus for forming an image on a medium based on image data.
The method of claim 1,
Further comprising a reading unit for reading an image on the original and generating image data,
The image forming unit, wherein the image forming unit forms an image on the media based on the image data generated by the reading unit while the condensation removing unit is executing the condensation removing process.
The method of claim 5,
A print data receiving unit for receiving print data from an external information processing device; And
The print data receiving unit further comprises a setting unit for making settings for preferentially processing image formation based on the received print data,
The image forming unit, according to the setting by the setting unit, forms an image on the media based on the print data received by the print data receiving unit while the condensation removing processing unit is executing the condensation removing processing .
The method of claim 1,
Further comprising a fan for discharging the air inside the image forming apparatus,
The image forming apparatus, wherein the condensation removing unit rotates the fan at a predetermined speed to remove condensation inside the image forming apparatus.
The method of claim 1,
Further comprising a determination unit for determining whether or not to perform the condensation removal processing by the condensation removal unit,
The image forming apparatus, wherein when the determination unit determines that the condensation removal process should be executed, the condensation removal unit executes the condensation removal process.
The method of claim 10,
Further comprising a temperature measuring unit for measuring the temperature around the image forming unit,
The image forming apparatus, wherein the determination unit determines whether or not to perform the condensation removal processing by the condensation removal unit based on the measurement result obtained by the temperature measurement unit.
The method of claim 1,
The facsimile job is not executed while the condensation removing unit is executing the condensation removing process,
An image forming apparatus, wherein a print job is executed after the condensation removal processing is stopped.
A control method of an image forming apparatus comprising a condensation removing unit that executes a condensation removing process, which is a process for removing condensation inside the image forming apparatus,
A receiving step of receiving image data; And
An image forming step of forming an image on the media based on the image data received in the receiving step,
When the image data is received in the receiving step while the condensation removing unit is executing the condensation removing processing, the condensation removing unit does not form an image on the media in the forming and forming step, and after the condensation removing processing is finished, the condensation removing unit A method of controlling an image forming apparatus, wherein an image is formed on the media in the image forming step based on image data received while the condensation removal process is being executed.
A recording medium storing a program for execution in an image forming apparatus having a condensation removing unit that executes a condensation removing process that is a process for removing condensation inside the image forming apparatus, the program comprising:
A receiving step of receiving image data; And
An image forming step of forming an image on the media based on the image data received in the receiving step,
When the image data is received in the receiving step while the condensation removing unit is executing the condensation removing processing, the condensation removing unit does not form an image on the media in the forming and forming step, and after the condensation removing processing is finished, the condensation removing unit A recording medium for forming an image on the media in the image forming step based on image data received while executing the condensation removal process.

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