JP2016161580A - Image formation apparatus and image formation system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide an image formation apparatus capable of achieving energy-saving by reducing power consumption as much as possible when the apparatus is not used by a user even if approaching of a human is sensed.SOLUTION: Image formation apparatuses 110, 120 comprise image formation parts 303 for forming images, human sensors 111, 121 for sensing a human, CPUs 153 for determining whether or not an operation is performed, CPU circuit parts 150 for notifying another image formation apparatus of state change notification when the CPUs 153 detect that a prescribed operation is performed, and printer control parts 301 for shifting the image formation apparatus into the stand-by state from the power-saving state when detecting approaching of a human and for shifting the image formation apparatus into the power-saving state with less power consumption than the stand-by state when detecting leaving of the human. The printer control part 301 shifts the image formation apparatus from the stand-by state into the power-saving state when receiving the state change notification from the other adjacent image formation apparatus.SELECTED DRAWING: Figure 3

Description

  The present invention relates to an image forming apparatus including a human sensor that detects that a user has approached, and an image forming system in which a plurality of image forming apparatuses are arranged adjacent to each other.

  In an electrophotographic image forming apparatus that forms an electrostatic latent image on a photosensitive member by irradiating a laser beam, the image forming apparatus is usually not used in order to quickly respond to a job that is input at any time. However, it has been applied without turning off the main switch.

  On the other hand, in order to reduce power consumption when the apparatus is not used, a sleep mode is set in the image forming apparatus. In the sleep mode, for example, energization of a motor built in the image forming apparatus is stopped, or power supply to accessories such as a post-processing apparatus and a paper feeding apparatus connected to the image forming apparatus is stopped.

  Some conventional image forming apparatuses automatically shift to a sleep mode when a predetermined time elapses without any operation by the user after the printing operation is completed. In such an image forming apparatus, the user normally returns from the sleep mode to the normal mode when the user operates the operation unit of the image forming apparatus.

  In recent years, image forming apparatuses equipped with human sensors have been developed to improve user convenience. The image forming apparatus provided with the human sensor returns from the sleep mode to the normal mode when the human sensor detects the approach of the person. Accordingly, the image forming apparatus returns from the sleep mode to the normal mode before the user starts the operation, so that the user can immediately use the image forming apparatus, and convenience is improved.

  Recently, various techniques have been proposed in order to optimize the transition timing to the sleep mode. For example, Patent Document 1 discloses an image forming apparatus having a function of shifting another apparatus to a sleep state via a network. This image forming apparatus has a function of rejecting the transition to the sleep state if the human sensor detects the human body when the sleep transition command is received.

  In addition, an image forming apparatus provided with a human sensor may improve user convenience, but may erroneously detect the approach of a person. In this case, the energized state continues even though it is not used. Therefore, it cannot be said to be a preferable state from the viewpoint of energy saving. In order to solve such a problem, Patent Document 2 discloses an image forming apparatus having a function of discriminating whether a person is approaching the image forming apparatus or simply passes in front of the image forming apparatus. Proposed. This image forming apparatus is configured not to return from the sleep state when a person simply passes in front of the apparatus.

JP 2001-066951 A JP 2013-186 211 A

  By the way, with the increase in the number of image forming apparatuses provided with human sensors, it is assumed that both adjacent image forming apparatuses are apparatuses including human sensors.

  FIG. 7 is a diagram for explaining the problems of the prior art.

  In FIG. 7, two image forming apparatuses 600 and 610 are installed adjacent to each other. The image forming apparatus 600 includes a human sensor 602, and the image forming apparatus 610 includes a human sensor 612. In this case, the detection areas in which the human sensors 602 and 612 detect the person partially overlap each other.

  In such a situation, for example, when the user P approaches the image forming apparatus 600 to use the image forming apparatus 600, the human sensor 602 detects the approach of a person. Similarly, the human sensor 612 of the adjacent image forming apparatus 610 also detects the approach of a person. Therefore, both the image forming apparatuses 600 and 610 return from the sleep state to the normal state. However, the user P plans to use the image forming apparatus 600 and does not plan to use the image forming apparatus 610. In this case, the image forming apparatus 610 consumes useless power to return to the normal state even though it is not scheduled to be used.

  That is, when a plurality of image forming apparatuses provided with human sensors are installed adjacent to each other, the normal state is detected until a person is detected by detecting a person and returning from the sleep state to the normal state even though the image forming apparatus is not used. There is a problem that power is wasted by being maintained.

  The present invention has been made to solve such a problem, and an image forming apparatus capable of realizing energy saving by reducing power consumption as much as possible when it is not used by a user even when a human approach is sensed. The purpose is to provide.

  In order to achieve the above object, according to a first aspect of the present invention, there is provided an image forming apparatus comprising: a forming unit that forms an image on a sheet material; a detecting unit that detects approaching and leaving of a person; Determining means for determining whether or not, and when the determining means detects that the predetermined operation has been performed, notifying means for notifying other adjacent image forming apparatuses of a notification that the state of the apparatus has changed When the detection unit detects the approach of a person, the image forming apparatus is shifted from the power saving state to the standby state. When the detection unit detects the leaving of the person, the image forming apparatus is moved from the standby state to the standby state. And a control unit that shifts to the power saving state that consumes less power than the state, and when the control unit receives a notification that the state has changed from another adjacent image forming apparatus, the image forming apparatus And wherein the shifting from the standby state to the power-saving state.

  According to the present invention, when the human sensor detects the approach of a person and returns from the sleep state to the normal state and then detects that a predetermined operation has been performed by the user, the human sensor detects other adjacent image forming apparatuses. To notify that the status of the device has changed. In this case, the image forming apparatus that has received the notification determines that the operator has approached to use the adjacent apparatus, not to use the own apparatus, and quickly returns to the sleep state. Thereby, power consumption can be reduced as much as possible to realize energy saving.

1 is a diagram illustrating a schematic configuration of an image forming system to which a plurality of image forming apparatuses are connected. FIG. 2 is a block diagram illustrating a control configuration of an image forming apparatus in the image forming system of FIG. 1. 3 is a flowchart illustrating a procedure of state change processing executed by the image forming apparatus in FIG. 1. It is a flowchart which shows the procedure of the operation input determination process performed by step S103 of FIG. FIG. 2 is a diagram illustrating a specific operation process of the image forming apparatus in FIG. 1. FIG. 6 is a sequence diagram showing operation contents of the image forming apparatus in FIG. 5 in time series. It is a figure for demonstrating the subject of a prior art.

  Hereinafter, embodiments will be described in detail with reference to the drawings.

  FIG. 1 is a diagram illustrating a schematic configuration of an image forming system in which a plurality of image forming apparatuses are connected.

  In FIG. 1, two image forming apparatuses 110 and 120 are arranged close to each other. The image forming apparatuses 110 and 120 are communicably connected to a personal computer (PC) 130 via a network 100 that is a communication line.

  The image forming apparatus 110 includes a human sensor 111, an operation display device 112, and a paper cassette 113. The image forming apparatus 110 is also connected to a document reading device 114 and a document feeding device 115 arranged at the top.

  The image forming apparatus 120 includes a human sensor 121, an operation display device 122, and a paper cassette 123. The image forming apparatus 120 is also connected to a document reading device 124 and a document feeding device 125 arranged at the top.

  The human sensors 111 and 121 are sensors for detecting a person, and the operation display devices 112 and 122 are interfaces for a user (operator) to input an operation instruction to the corresponding image forming apparatus. . The paper cassettes 113 and 123 are cassettes that store sheet materials, respectively, and are detachably attached to the corresponding image forming apparatuses in order to set the sheet materials. The document feeders 115 and 125 sequentially feed a plurality of documents to the document readers 114 and 124, respectively. The document readers 114 and 124 respectively read the images of the fed documents.

  Image data for printing is transmitted from the PC 130 to the designated image forming apparatus via the network 100. The image data transmitted from the PC 130 is printed on a sheet material in the designated image forming apparatus. The image data transmitted from the PC 130 may not be printed immediately, but may be temporarily stored and stored in the image forming apparatus that has received the transmission, and may be printed after a predetermined time has elapsed.

  The image data transmitted from the PC 130 and stored in the image forming apparatus is sent to the corresponding image forming apparatus by the user by selecting the image data to be printed using the operation display device and instructing the start of printing. The image is received by the received image forming apparatus.

  Next, the control configuration of the image forming apparatus 110 in FIG. 1 will be described.

  FIG. 2 is a block diagram showing a control configuration of the image forming apparatus in the image forming system of FIG. The control configuration of the image forming apparatus 120 is the same as the control configuration of the image forming apparatus 110.

  In FIG. 2, the image forming apparatus 110 includes a CPU circuit unit 150. The CPU circuit unit 150 includes a CPU 153, a ROM 151, and a RAM 152. The CPU 153 controls each element of the image forming apparatus 110. The ROM 151 stores a control program. The RAM 152 stores data for control.

  A document feeder control unit 101 and a document detection sensor 102 are connected to the CPU circuit unit 150. The document feeder control unit 101 is a block that controls the document feeder 115. The document detection sensor 102 detects that a document has been placed on the document tray of the document feeder 115 and that the document has been removed, and notifies the document feeder controller 101.

  An image reader control unit 201 is connected to the CPU circuit unit 150. The image reader control unit 201 is a block that controls the document reading device 114. The image reader control unit 201 controls the document reading device 114 and also functions as a document detection unit that detects that a document is placed on the pressure plate of the document reading device 114.

  An image signal control unit 202 is connected to the CPU circuit unit 150. The image signal control unit 202 receives the image data generated by the image reader control unit 201 and the image data transmitted from the PC 130. The image signal control unit 202 converts image data in response to an instruction from the CPU circuit unit 150 and transmits the converted image data to a printer control unit 301 described later.

  A printer control unit 301 is connected to the CPU circuit unit 150. In addition, a sheet material conveyance unit 302, an image forming unit 303, and a fixing unit 304 are connected to the printer control unit 301. A printer control unit 301 controls the sheet material conveyance unit 302, the image forming unit 303, and the fixing unit 304. The sheet material conveying unit 302 conveys the sheet material to the outside of the image forming apparatus via the image forming unit 303 and the fixing unit 304. The image forming unit 303 forms a latent image based on the image data, visualizes the latent image with toner, and transfers the latent image to a sheet material. The fixing unit 304 fixes the toner image transferred to the sheet material to the sheet material by heat.

  The printer control unit 301 sends the image data received from the image signal control unit 202 to the image forming unit 303 and simultaneously conveys the sheet material to the sheet material conveyance unit 302. The toner image is transferred to the sheet material and then conveyed to the fixing unit 304. The sheet material on which the toner image is fixed by the fixing unit 304 is discharged out of the image forming apparatus.

  An attachment / detachment sensor 305 is connected to the sheet material conveyance unit 302. The attachment / detachment sensor 305 functions as an attachment / detachment detection unit that detects attachment / detachment of the sheet cassette 113 from the image forming apparatus 110. The paper cassette 113 includes a sensor (not shown) that detects whether or not the sheet material is stored.

  An external I / F (interface) 209 connects the image signal control unit 202 to the network 100. The external I / F 209 is a block that controls communication with the outside. The external I / F 209 receives image data from the PC 130 and transmits it to the image signal control unit 202. The CPU 153 checks the information regarding the print timing included in the print data received via the external I / F 209, determines whether to print immediately, and stores the image data in the storage device 154 described later if printing is not performed immediately. The external I / F 209 is controlled.

  A storage device 154 is connected to the CPU circuit unit 150. The storage device 154 is composed of a hard disk, for example, and stores image data.

  A human sensor 111 is connected to the CPU circuit unit 150, and the human sensor 111 detects the approach of a person and notifies the CPU circuit unit 150 of it. The human sensor 111 detects that a person has left the image forming apparatus 110 and notifies the CPU circuit unit 150 of it.

  An operation display device control unit 401 is connected to the CPU circuit unit 150. The operation display device control unit 401 is a block that controls the operation display device 112. Further, the operation display device control unit 401 controls the operation display device 112 and displays a screen for registering information of other image forming devices connected to the network 100 on the screen of the operation display device 112. To do. The user can register the network address of the adjacent image forming apparatus by operating the operation display device 112. Network addresses of other image forming apparatuses registered by the user are stored in the storage device 154.

  The CPU circuit unit 150 also instructs the printer control unit 301 to control power consumption. The printer control unit 301 switches power consumption in accordance with an instruction from the CPU circuit unit 150. That is, the printer control unit 301 sets a normal state in which printing is possible and a power saving state (sleep state) that consumes less power than the normal state as states for power control. In the power saving state, the control temperature of the fixing unit 304 is set low to reduce power consumption. The normal state includes a printing state in which printing is performed and a standby state (standby state) in which printing is started.

  Further, when the state of the image forming apparatus 110 changes due to operation of the operation display device 112 or the like, the CPU circuit unit 150 transmits a state change notification to another image forming apparatus via the external I / F 209. Tell the state has changed. The state change notification is registered in the storage device 154, and is transmitted to the network address of the adjacent image forming apparatus to be notified. Further, the CPU circuit unit 150 receives a state change notification transmitted from another adjacent image forming apparatus via the external I / F 209.

  Next, state change processing executed by the image forming apparatus 110 will be described. The state change process is executed by the CPU 153 of the CPU circuit unit 150 according to the procedure of the state change process program stored in the ROM 151.

  FIG. 3 is a flowchart showing the procedure of the state change process executed by the image forming apparatus 110. Note that similar state change processing is also executed in the image forming apparatus 120.

  3, in the sleep state of the image forming apparatus 110, the CPU 153 first determines whether or not the human sensor 111 has detected the presence of a person, and waits until a person is detected (step S101). After the human sensor 111 detects a person (“YES” in step S101), the CPU 153 controls the printer control unit 301 to return to sleep, that is, shift from the sleep state to the normal state (step S102).

  After shifting to the normal state, the CPU 153 executes an operation input determination process for confirming that an operation is input from the user to the image forming apparatus 110 (step S103). The operation input determination process as a subroutine will be described in detail later with reference to the drawings.

  Next, the CPU 153 determines whether any operation is input to the image forming apparatus 110 by the user based on the result of the operation input determination (step S103) (step S104). As a result of the determination in step S104, when the user inputs some operation input to the image forming apparatus 110 (“YES” in step S104), the CPU 153 advances the process to step S105. That is, the CPU 153 informs other adjacent image forming apparatuses registered in the storage device 154, for example, the image forming apparatus 120, that the user inputs an operation to the own apparatus and that the state has changed. A change notification is sent (step S105).

  After notifying the other image forming apparatus 120 of the state change notification, the CPU 153 confirms whether or not the human sensor 111 detects a person (step S106). As a result of the determination in step S106, when a person is detected by the human sensor 111 ("YES" in step S106), the CPU 153 determines whether there is a state change notification from another image forming apparatus, for example, the image forming apparatus 120. (Step S108). As a result of the determination in step S108, when there is a state change notification (“YES” in step S108), the CPU 153 shifts the image forming apparatus 110 to the sleep state (step S109). Next, as in step S106, the CPU 153 determines whether or not the human sensor 111 detects a person (step S110), waits until the person leaves, leaves the person, and returns the process to step S101.

  On the other hand, as a result of the determination in step S108, when there is no state change notification from another image forming apparatus (“NO” in step S108), the CPU 153 returns the process to step S103 and executes the operation input determination process.

  Further, as a result of the determination in step S106, when the human sensor 111 has not detected a person ("NO" in step S106), the CPU 153 advances the process to step S107. That is, the CPU 153 assumes that a person has left the front of the image forming apparatus 110, shifts the state of the image forming apparatus 110 from the normal state to the sleep state (step S107), and then returns the process to step S101.

  In this case, if the person is not detected by the human sensor 111 as a result of the determination in step S106, even if there is a state change notification from another image forming apparatus, the person leaves from the front of the image forming apparatus 110. After that, the status change notification is not accepted.

  On the other hand, if the result of the determination in step S104 is that the user has not performed any operation input on the image forming apparatus 110 (“NO” in step S104), the CPU 153 changes the state of the other image forming apparatuses. The process proceeds to step S106 without notification.

  According to the processing of FIG. 3, when the human sensor 111 detects that a person has approached and returns from sleep (step S <b> 102), the user leaves without inputting any operation to the image forming apparatus 110. Return to the sleep state (step S107).

  Further, after detecting that a person has approached by the human sensor 111 and returning from sleep, when a state change notification is received from another device without being operated by the user (“YES” in step S108), the sleep is performed. The state is shifted (step S109).

  Also, after detecting that the person is approaching by the human sensor 111 and returning from sleep (step S102), when not operated by the user and not receiving a state change notification from another device ("NO" in step S108). ), And waits until it is operated (step S104).

  As described above, in the plurality of image forming apparatuses arranged close to each other, even when the human sensor 111 detects the approach of the person and the sleeve returns, if the user does not operate the apparatus, the sleep state Wait until you return to or operate. As a result, it is possible to perform an appropriate operation according to a state change with respect to a plurality of image forming apparatuses arranged close to each other, so that power consumption can be minimized.

  Next, the operation input determination process executed in step S103 of FIG. 3 will be described.

  The operation input determination process for determining whether or not the user has performed an operation on the image forming apparatus is similar to the state change process described above, and the procedure of the operation input determination process program stored in the ROM 151 by the CPU 153 of the CPU circuit unit 150 is as follows. Follow the instructions.

  FIG. 4 is a flowchart showing the procedure of the operation input determination process executed in step S103 of FIG.

  In the operation input determination process, the CPU 153 first controls the operation display device control unit 401 to determine whether or not the operation display device 112 has been operated by the user (step S201). As a result of the determination in step S201, when the operation display device 112 is operated (“YES” in step S201), the CPU 153 advances the process to step S206. That is, the CPU 153 determines that there is a user operation input to the operation display device 112 (step S206), and ends this process.

  On the other hand, if the result of determination in step S201 is that the operation display device 112 has not been operated (“NO” in step S201), the CPU 153 advances the processing to step S202. That is, the CPU 153 controls the sheet material conveyance unit 302 that monitors the attachment / detachment sensor 305 to determine whether or not the sheet cassette 113 has been attached / detached (step S202). If the result of determination in step S202 is that the paper cassette 113 has been attached or detached (“YES” in step S202), the CPU 153 determines that there is an operation input (step S206), and ends this processing.

  If the result of the determination in step S202 is that the paper cassette 113 has not been attached or detached (“NO” in step S202), the CPU 153 advances the process to step S203. That is, the CPU 153 controls the image reader control unit 201 to determine whether or not the document presence / absence detection result on the pressure plate of the document reading device 114 has changed (step S203). As a result of the determination in step S203, when the detection result by the image reader control unit 201 changes from the presence of an original to no original or from the absence of an original to the presence of an original, the CPU 153 determines that there is an operation input by the user (step S206), this process is terminated.

  If the detection result of the image reader control unit 201 has not changed as a result of the determination in step S203 (“NO” in step S203), the CPU 153 advances the process to step S204. That is, the CPU 153 determines whether or not the document feeder control unit 101 that monitors the document detection sensor 102 has detected the removal or insertion of a document on the document tray of the document feeder 115 (step S204). As a result of the determination in step S204, if the detection result of the document detection sensor 102 changes from the presence of a document to the absence of a document or from the absence of a document to the presence of a document, the CPU 153 determines that there is an operation input by the user (step S206). This process ends.

  On the other hand, if the detection result of the document detection sensor 102 does not change as a result of the determination in step S204 (“NO” in step S204), the CPU 153 determines that there is no operation input by the user (step S205), and performs this process. finish.

  According to the process of FIG. 4, it is determined whether the operation display apparatus 112 was operated by controlling the operation display apparatus control part 401 (step S201). Further, the sheet material conveyance unit 302 is controlled to determine whether or not the paper cassette 113 has been attached or detached (step S202). Further, the image reader control unit 201 is controlled to determine whether or not the document presence / absence detection result on the pressure plate of the document reading device 114 has changed (step S203). Further, the document feeder control unit 101 is controlled to determine whether or not the insertion / removal of the document on the document tray of the document feeder 115 is detected (step S204). As a result, it is possible to accurately determine whether or not the user inputs any operation to the image forming apparatus 110.

  Next, specific operations of the image forming apparatus 110 in FIG. 1 and the image forming apparatus 120 arranged adjacent to the image forming apparatus 110 will be described.

  FIG. 5 is a diagram showing specific operation steps of the image forming apparatus in FIG. 1, and FIG. 6 is a sequence diagram showing operation contents of the image forming apparatus in FIG. 5 in time series.

  5 and 6, the first image forming apparatus 110 and the second image forming apparatus 120 are controlled according to the flowcharts described in FIGS. 3 and 4, respectively.

  In FIG. 5A, the first image forming apparatus 110 and the second image forming apparatus 120 are installed facing each other, and the human sensor 111 of the first image forming apparatus 110 is detected by a broken line. It is set to detect a person in the area 20. On the other hand, the human sensor 121 of the second image forming apparatus 120 is set to detect a person in the detection area 21 indicated by a broken line. The detection area 20 and the detection area 21 partially overlap. The first image forming apparatus 110 and the second image forming apparatus 120 are both in an initial state, and the human sensors 111 and 121 are not detecting a person, and are in a sleep state with low power consumption. . That is, both the first image forming apparatus 110 and the second image forming apparatus 120 repeat step S101 in FIG.

  In FIG. 6, the sleep states of the first image forming apparatus 110 and the second image forming apparatus 120 are indicated by a sleep state 22 and a sleep state 23, respectively.

  Consider a case where the user P approaches the image forming apparatus 110 in order to use the first image forming apparatus 110 in such a state.

  FIG. 5B shows a state where the user P stands in front of the first image forming apparatus 110. This state is represented by the timing 24 when the user P arrives in FIG.

  At this time, the user P covers both the detection area 20 that is the detection range of the first human sensor 111 and the detection area 21 that is the detection range of the second human sensor 121. For this reason, both the first human sensor 111 and the second human sensor 121 detect a person. Accordingly, both the first image forming apparatus 110 and the second image forming apparatus 120 proceed to step S102 in FIG. 3, and return from the sleep state, that is, return from the sleep state to the normal state (standby state).

  In FIG. 6, the standby states of the first image forming apparatus 110 and the second image forming apparatus 120 are represented by a standby state 25 and a standby state 26, respectively.

  After the first image forming apparatus 110 and the second image forming apparatus 120 return from sleep (step S102), the first image forming apparatus 110 and the second image forming apparatus 120 perform operation input determination processing, respectively. It is executed (step S103). The operation input determination process determines whether or not any operation is input by the user.

  In the state of FIG. 5B, since the operation display device 112 of the first image forming apparatus 110 and the operation display device 122 of the second image forming apparatus 120 are not operated, the determination result of step S104 is Both are NO, and the process proceeds to step S106.

  In step S <b> 106, it is determined whether the human sensor 111 of the first image forming apparatus 110 and the human sensor 121 of the second image forming apparatus 120 are detecting a person. In the state of FIG. 5B, since the human sensor 111 of the first image forming apparatus 110 and the human sensor 121 of the second image forming apparatus 120 both detect a person, the first image formation is performed. Both the apparatus 110 and the second image forming apparatus 120 proceed to step S108.

  In step S108, it is determined whether there has been a state change notification from another device. In the state of FIG. 5B, the first image forming apparatus 110 and the second image forming apparatus 120 have not received the state change notification. Therefore, both devices return to step S103. That is, after the user P is detected, until the user P executes some operation input, both devices repeat the steps of step S103 → step S104 → step S106 → step S108 → step S103 in FIG.

  Next, consider a case where the user P operates the first operation display device 112 in order to use the first image forming apparatus 110 as shown in FIG. This state is represented by a state 27 in which the user has performed an operation input (job start) in FIG.

  In the state of FIG. 5C, in the first image forming apparatus 110, the determination result of step S104 is YES. Accordingly, the first image forming apparatus 110 proceeds to step S105. In step S105, the other apparatus, in this case, the second image forming apparatus 120 is notified that the apparatus has been operated and the state has changed. That is, the first image forming apparatus 110 transmits a state change notification to the second image forming apparatus 120. In FIG. 6, the state change notification is represented by an arrow 28.

  Next, the first image forming apparatus 110 proceeds to step S106 in FIG. 3, and determines whether or not the first human sensor 111 detects a person. As a result of the determination, if the first human sensor 111 detects a person, the first image forming apparatus 110 proceeds to step S108. That is, the first image forming apparatus 110 that once detected some operation input by the user P repeats step S103 → step S104 → step S106 → step S108 → step S103 again. This state is represented by a printing state 30 and a standby state 31 in FIG.

  On the other hand, since the second image forming apparatus 120 receives the state change notification from the first image forming apparatus 110, the determination result in step S108 of FIG. 3 is YES. Therefore, thereafter, the process proceeds to step S109, and the apparatus state is shifted from the normal state to the sleep state. This state is represented by a sleep state 29 in FIG.

  Next, the second image forming apparatus 120 proceeds to step S110, determines whether or not the second human sensor 121 detects a person, and while the human sensor 121 detects a person. Step S109 is repeated and the sleep state is maintained.

  5C, the first image forming apparatus 110 repeats step S103 → step S104 → step S106 → step S108 → step S103, and the second image forming apparatus 120 repeats step S109. ing. Together, the current state is maintained until the user P leaves.

  Next, consider a case where the user P leaves the image forming apparatus 110 as shown in FIG. This state is represented by the timing 32 at which the user P leaves in FIG.

  When the user P leaves the image forming apparatus, the first image forming apparatus 110 does not detect the person at the first human sensor 111 in step S106 in FIG. 3, so the determination result in step S106 is NO. Then, the process proceeds to step S107. That is, the first image forming apparatus 110 shifts the apparatus state from the normal state to the sleep state, and then returns the process to step S101. This state is represented by a sleep state 33 in FIG.

  When the user P leaves the image forming apparatus, the second image forming apparatus 120 does not detect the person in step S110, and therefore the determination result in step S110 is NO. The process returns to step S101.

  According to the present embodiment, when a user P who is a person approaches a place where a plurality of image forming apparatuses including human sensors are arranged adjacent to each other, the image forming apparatuses 110 and 120 that detect the user P are: Return from sleep to normal. Thereafter, the image forming apparatus 110 whose operation display apparatus has been operated by the user P notifies the other image forming apparatus 120 of a state change notification indicating that the apparatus has been operated and the state has changed. The other image forming apparatus 120 that has received the state change notification senses that the user P is approaching and transitions from the sleep state to the normal state (standby state), but senses that the user P is not operated and sleeps again. Return to state. Accordingly, it is possible to shorten the time for maintaining the normal state without operating the image forming apparatus 120 that is not operated by the user P as much as possible, and avoid unnecessary power consumption.

  Further, according to the present embodiment, when the user P leaves the image forming apparatus, the image forming apparatus 110 operated by the user P and in the normal state quickly returns from the normal state to the sleep state. As described above, also in the image forming apparatus 110 operated by the user, the time for maintaining the normal state without being operated is shortened as much as possible, so that useless power consumption can be avoided.

  In the present embodiment, the image forming system in which the two image forming apparatuses 110 and 120 are connected by the network 100 has been described. However, the present invention is not limited to this, and three or more image forming apparatuses are connected to each other. Even if it is done, the same effect is acquired.

  In the present embodiment, the network 100 has been described as a wired communication network, but may be a wireless communication network.

100 Network 110 Image Forming Device 111 Human Sensor 112 Operation Display Device 113 Paper Cassette 114 Document Reading Device 115 Document Feeding Device 120 Image Forming Device 121 Human Sensor 122 Operation Display Device 123 Paper Cassette 124 Document Reading Device 125 Document Feeding Device 130 Personal computer (PC)
150 CPU circuit section 151 ROM
152 RAM
153 CPU

Claims (8)

Forming means for forming an image on a sheet material;
Detection means for detecting the approach and leaving of a person;
Determination means for determining whether or not a predetermined operation has been performed by the operator;
A notification means for notifying other adjacent image forming apparatuses of a notification that the status of the apparatus has changed when the determination means detects that the predetermined operation has been performed;
When the detection unit detects the approach of a person, the image forming apparatus is shifted from the power saving state to the standby state. When the detection unit detects the leaving of the person, the image forming apparatus is moved from the standby state to the standby state. And a control means for shifting to the power saving state with low power consumption,
The control unit causes the image forming apparatus to shift from the standby state to the power saving state when a notification that the state has changed is received from another adjacent image forming apparatus. The other image forming apparatus includes a detecting unit that detects approach and leaving of the person,
The detection area of a detection unit included in the image forming apparatus and a detection area of a detection unit included in the other image forming apparatus adjacent to the image forming apparatus partially overlap each other. Image forming apparatus. First document detection means for detecting that the document is placed on a reading means for reading the document;
Second document detecting means for detecting that the document is placed on a feeding means for feeding the document to the reading means;
An attachment / detachment detecting means for storing the sheet material and detecting attachment / detachment of the storage means configured to be detachable from the image forming apparatus from the image forming apparatus;
When the first document detection unit detects a change in the presence or absence of a document in the reading unit, or when the second document detection unit detects a change in the presence or absence of a document in the feeding unit, or the attachment / detachment detection The determination unit determines that a predetermined operation has been performed on the image forming apparatus by the operator when the unit detects a change in attachment / detachment of the storage unit from the image forming apparatus. Item 3. The image forming apparatus according to Item 1 or 2. The image forming apparatus includes registration means for registering another image forming apparatus to which the notification means notifies that the state has changed,
The image according to any one of claims 1 to 3, wherein the notification unit notifies the other image forming apparatus registered in the registration unit that the state has changed. Forming equipment. Determining means for determining whether or not to accept a notification that the state has changed;
The determination unit accepts the notification that the state has changed when the detection unit has already detected that the person has left when the other image forming apparatus has notified that the state has changed. 5. The image forming apparatus according to claim 1, wherein the image forming apparatus determines not to perform the operation.   5. The image forming system according to claim 1, wherein the image forming apparatus according to claim 1 and the other image forming apparatus are connected to each other via a communication network. A personal computer is connected to the communication network,
The image forming system according to claim 6, wherein the forming unit forms an image on the sheet material using image data received from the personal computer. The image forming system according to claim 7, wherein the image forming apparatus includes a storage unit that stores the image data.

Images