The present invention relates to an image forming apparatus that forms an image on a sheet, and a sheet bonding apparatus that bonds sheets together.
Japanese Patent Application Laid-Open No. 2013-43751 discloses an image forming apparatus that forms a bonding toner pattern on a sheet in addition to a visible image for recording information by an electrophotographic process and bonds sheets together via the bonding toner pattern by stacking the sheets and heating the sheet stack. Japanese Patent Application Laid-Open No. 2005-215230 discloses an image forming apparatus that manufactures a sheet material bundle of a larger sheet number by repeating an operation of heating and pressurizing sheet materials, on each of which a bonding toner layer is formed, by a heating pressurizing member. The operation of heating and pressurizing is performed on three sheet materials at a time.
The present invention provides an image forming apparatus that can change a toner amount at a bonded portion as necessary can be provided.
According to an aspect of the invention, an image forming apparatus includes an image forming portion configured to form an image on a sheet and apply bonding toner on the sheet, and a bonding portion including a pressurizing member and configured to bond sheets together via the bonding toner by performing a bonding operation of pressurizing and heating a sheet stack by the pressurizing member, wherein the bonding portion is configured to, in a state in which a succeeding sheet is stacked on a sheet stack that has been bonded in a previous bonding operation, perform a next bonding operation to bond a first surface of an uppermost sheet of the bonded sheet stack to a second surface of the succeeding sheet opposing the first surface, the next bonding operation and the previous bonding operation each being the bonding operation, and wherein an amount of the bonding toner that the image forming portion applies on the first surface per unit area of the first surface is smaller than an amount of the bonding toner that the image forming portion applies on the second surface per unit area of the second surface.
According to another aspect of the invention, an image forming apparatus includes an image forming portion configured to form an image and a bonding toner image on a sheet, and a bonding portion configured to bond sheets together via the bonding toner image by pressurizing and heating a sheet stack, and wherein the image forming portion is configured to form the image in an image region on the sheet by using toner, and form the bonding toner image in a bonding region on the sheet different from the image region by using the toner, and wherein a toner amount per unit area in the bonding region is different from a toner amount per unit area in the image region.
According to another aspect of the invention, a sheet bonding apparatus includes an application portion configured to apply bonding toner on a sheet, and a bonding portion including a pressurizing member and configured to bond sheets together via the bonding toner by performing a bonding operation of pressurizing and heating a sheet stack by the pressurizing member, wherein the bonding portion is configured to, in a state in which a succeeding sheet is stacked on a sheet stack that has been bonded in a previous bonding operation, perform a next bonding operation to bond a first surface of an uppermost sheet of the bonded sheet stack to a second surface of the succeeding sheet opposing the first surface, the next bonding operation and the previous bonding operation each being the bonding operation, and wherein an amount of the bonding toner that the application portion applies on the first surface per unit area of the first surface is smaller than an amount of the bonding toner that the application portion applies on the second surface per unit area of the second surface.
According to another aspect of the invention, a n image forming apparatus includes an image forming portion configured to form an image on a sheet and apply bonding toner on the sheet, and a bonding portion including a pressurizing member and configured to bond sheets together via the bonding toner by performing a bonding operation of pressurizing and heating a sheet stack by the pressurizing member, wherein the bonding portion is configured to, in a state in which a succeeding sheet is stacked on a sheet stack bonded in a previous bonding operation, perform a next bonding operation to bond a first surface of an uppermost sheet of the bonded sheet stack to a second surface of the succeeding sheet opposing the first surface, the next bonding operation and the previous bonding operation each being the bonding operation, and wherein a toner density of the bonding toner that the image forming portion applies on the first surface is lower than a toner density of the bonding toner that the image forming portion applies on the second surface.
According to another aspect of the invention, an image forming apparatus includes an image forming portion configured to form an image on a sheet and apply bonding toner on the sheet, and a bonding portion including a pressurizing member and configured to bond sheets together via the bonding toner by performing a bonding operation of pressurizing and heating a sheet stack by the pressurizing member, wherein the bonding portion is configured to, in a state in which a succeeding sheet is stacked on a sheet stack bonded in a previous bonding operation, perform a next bonding operation to bond a first surface of an uppermost sheet of the bonded sheet stack to a second surface of the succeeding sheet opposing the first surface, the next bonding operation and the previous bonding operation each being the bonding operation, and wherein a thickness of a layer of the bonding toner that the image forming portion forms on the first surface is smaller than a thickness of a layer of the bonding toner that the image forming portion forms on the second surface.
Further features of the present invention will become apparent from the following description of exemplary embodiments with reference to the attached drawings.
Embodiments according to the present disclosure will be described below with reference to drawings.
First, the overall configuration of an image forming apparatus will be described with reference to
The image forming apparatus 1S includes a printer portion 1 (image forming apparatus body) including an image forming unit 1e of an electrophotographic system, an intermediate conveyance unit 26 coupled to the printer portion 1, and a post-processing apparatus 4 (sheet processing apparatus) coupled to the intermediate conveyance unit 26. The image forming apparatus 1S is an image forming system constituted by a plurality of apparatuses. To be noted, the functions of the apparatuses included in the image forming apparatus 1S of the present embodiment may be disposed in one casing.
As illustrated in
In the present embodiment, the maximum size of the sheet P on which an image can be formed by the printer portion 1 is the A4 size (297 mm×210 mm). In addition, the printer portion 1 can perform the image formation by conveying the sheet P of the A4 size in the longitudinal direction (long-side feeding direction, a direction in which the long side of the sheet P of the A4 size is parallel to the sheet conveyance direction).
The image forming unit 1e is an electrophotographic unit of a tandem-type intermediate transfer system including four process cartridges 7n, 7y, 7m, and 7c, a scanner unit 2 serving as an exposing unit, and a transfer unit 3. The process cartridge is a unit including a plurality of components in charge of an image forming process so as to be collectively replaceable.
The image forming unit 1e also functions as an application portion that applies an adhesive on the sheet P as will be described later. The image forming apparatus 1S including the image forming unit 1e and a booklet making apparatus 50 that will be described later is an example of a sheet bonding apparatus that forms a product in which sheets P are bonded together.
The process cartridges 7n, 7y, 7m, and 7c respectively include photosensitive drums Dn, Dy, Dm, and Dc serving as image bearing members, charging rollers, and developing units. The charging rollers each function as a charging portion that charges corresponding one of the photosensitive drums Dn, Dy, Dm, and Dc. The developing units each include a toner accommodating portion that accommodates toner serving as developer and a developing roller serving as a developer bearing member that bears the toner, and each supply toner to corresponding one of the photosensitive drums Dn, Dy, Dm, and Dc.
Among the four process cartridges 7n, 7y, 7m, and 7c, the three process cartridges 7y, 7m, and 7c on the right side in the drawing are process cartridges for forming a visible image on the sheet P. The process cartridges 7y, 7m, and 7c respectively form yellow, magenta, and cyan toner images. The yellow, magenta, and cyan toners accommodated in the process cartridges 7y, 7m, and 7c are each image toner for forming an image on the sheet P (recording toner for recording information).
In contrast, the process cartridge 7n on the left side in the drawing is a process cartridge for applying toner for bonding (bonding toner or powder adhesive) that bonds sheets together after printing on the sheet P. The process cartridge 7n forms a toner image (bonding toner image) of the bonding toner for applying an adhesive on the sheet P by the electrophotographic process similarly to the process cartridges 7y, 7m, and 7c. That is, part of the plurality of process cartridges 7n, 7y, 7m, and 7c included in the image forming unit 1e forms a visible image by using toner, and the other part of the cartridges forms an adhesive layer on the sheet P by using the bonding toner. The bonding toner may be colorless transparent toner, or may be colored toner.
In the present embodiment, black is expressed by process black obtained by superimposing yellow, magenta, and cyan toners on each other in the case of forming a black image such as a text. However, for example, a fifth process cartridge including black toner may be added to the image forming unit 1e such that a black image can be expressed by black image toner. The configuration is not limited to this, and the types and number of image toner and bonding toner may be changed in accordance with the application of the image forming apparatus 1S.
A laser driving circuit incorporated in the scanner unit 2 will be described.
The scanner unit 2 is an example of an exposing portion that forms electrostatic latent images by performing exposure by irradiating the photosensitive drums Dn, Dy, Dm, and Dc of the process cartridges 7n, 7y, 7m, and 7c with light, respectively. The scanner unit 2 includes a semiconductor laser 100 serving as a light source, a polygonal mirror 101, a synchronization sensor 102, and the laser driving circuit 115. The laser driving circuit 115 includes a light emission control portion 103, and a driving current generation portion 104. Four sets of the semiconductor laser 100, the synchronization sensor 102, and the laser driving circuit 115 are provided in correspondence with the four photosensitive drums Dn, Dy, Dm, and Dc.
Laser light L1 emitted from the semiconductor laser 100 is reflected by the polygonal mirror 101 that is rotationally driven. The surface of the photosensitive drum D is scanned by reflected scanning light L3 in a main scanning direction via an unillustrated ft lens. In addition, as a result of light L2 scanning the synchronization sensor 102, a main scanning synchronization signal 108 is output from the synchronization sensor 102. The light L2 is part of the laser light L1 emitted from the semiconductor laser 100.
The image forming apparatus 1S includes a controller 107 serving as a controller that controls the image forming apparatus 1S, and a central processing unit: CPU 106. The controller 107 outputs an image signal 109 corresponding to each color on the basis of the main scanning synchronization signal 108 to the light emission control portion 103. The light emission control portion 103 outputs a laser driving current 112 that is a current supplied to the semiconductor laser 100 in accordance with the image signal 109, and controls the drive of the semiconductor laser 100.
The CPU 106 performs serial communication with the driving current generation portion 104 via a serial communication signal 110. The driving current generation portion 104 outputs a laser driving current amount signal 111 on the basis of information transmitted from the CPU 106, and controls the current amount of the laser driving current 112. The laser driving current 112 is controlled to a current amount based on the laser driving current amount signal 111. The laser light emitted from the scanner unit 2 of the present embodiment onto the photosensitive drum D is of a predetermined light amount regardless of the position in the main scanning direction.
As the image toner of the present embodiment, known image toner can be used. Among those, image toner containing thermoplastic resin as binder resin is preferred. The thermoplastic resin is not particularly limited, and resins conventionally used for image toner, such as polyester resin, vinyl resin, acrylic resin, and styrene acrylic resin can be used. The image toner may contain a plurality of these resins. The image toner contains a colorant, a magnetic body, a charge control agent, a wax, an external additive, and the like.
As the bonding toner of the present embodiment, toner containing thermoplastic resin can be used. The resin that can be used for the thermoplastic resin is not particularly limited, and examples thereof include polyester resin, vinyl resin, acrylic resin, styrene acrylic resin, and the like similarly to the image toner. The bonding toner may contain a plurality of these resins. The bonding toner may contain a colorant, a magnetic body, a charge control agent, a wax, an external additive, and the like similarly to the image toner. In addition, the same toner as the image toner may be used as the bonding toner if the toner satisfies the adhesivity.
The transfer unit 3 of the present embodiment includes a transfer belt 3a serving as an intermediate transfer member (secondary image bearing member), a secondary transfer opposing roller 3b, and a driving roller 3c. The transfer belt 3a is a belt member stretched over the secondary transfer opposing roller 3b and the driving roller 3c. The transfer belt 3a opposes the photosensitive drums Dn, Dy, Dm, and Dc of the process cartridges 7n, 7y, 7m, and 7c on the outer peripheral surface thereof. Primary transfer rollers Fn, Fy, Fm, and Fc are disposed on the inner peripheral side of the transfer belt 3a at positions respectively corresponding to the photosensitive drums Dn, Dy, Dm, and Dc. The transfer belt 3a is conveyed in a counterclockwise direction in the drawing by being rotationally driven by the driving roller 3c.
The printer portion 1 includes a secondary transfer roller 5 serving as a transfer member at a position opposing the secondary transfer opposing roller 3b with the transfer belt 3a therebetween. A transfer nip 5n between the secondary transfer roller 5 and the transfer belt 3a is a transfer portion (secondary transfer portion) for transferring a toner image from the transfer belt 3a to the sheet P.
The fixing unit 6 is an example of a fixing portion that fixes the toner image formed on the sheet P to the sheet P. The fixing unit 6 is a unit (image heating unit) of a thermal fixation system that fixes the toner image by heating.
The fixing unit 6 includes a heating roller 6b serving as a fixing member, a halogen heater 6a serving as a heat source (heating portion) included in the heating roller 6b, and a pressurizing roller 6c serving as an opposing member opposing the heating roller 6b. The heating roller 6b is rotationally driven by a drive source. In addition, the heating roller 6b and the pressurizing roller 6c are in pressure contact by an urging member such as a spring, and thus a fixing nip 6n is formed between the heating roller 6b and the pressurizing roller 6c.
The fixing unit 6 includes a temperature detection element such as a thermistor that detects the temperature of the heating roller 6b. The controller of the image forming apparatus 1S adjusts the power supplied to the halogen heater on the basis of the detection signal of the temperature detection element, and thus performs temperature control such that the heating roller 6b is at a predetermined target temperature (fixing temperature).
To be noted, the heat source (heating portion) may be a ceramic heater in which a pattern of a heat generating resistor is formed on a ceramic substrate, an induction heating mechanism that generates heat in a conductive layer of the heating roller 6b by induction heating, or the like. The fixing member is not limited to the heating roller 6b having rigidity, and may be a thin film formed from a resin having high heat resistance such as polyimide resin or polyamideimide resin, or metal such as stainless steel.
The image forming operation of the printer portion 1 will be described (see
When the image forming operation is started, the sheets P accommodated in the cassette 8 are fed one by one from the cassette 8 by the feeding roller 8a. In addition, the printer portion 1 is also capable of feeding sheets P set on a multi-purpose tray 20 (manual feed tray) one by one. The fed sheet P is conveyed toward the transfer nip 5n by a conveyance roller pair 8b.
In the image forming unit 1e, in parallel with the feeding of the sheet P, the process cartridges 7n, 7y, 7m, and 7c are sequentially driven, and the photosensitive drums Dn, Dy, Dm, and Dc are rotationally driven. The surface of each of the photosensitive drums Dn, Dy, Dm, and Dc is imparted with uniform charge by a charging roller. In addition, the scanner unit 2 irradiates the photosensitive drums Dn, Dy, Dm, and Dc with laser light modulated on the basis of image data, and thus an electrostatic latent image is formed on the surface of each of the photosensitive drums Dn, Dy, Dm, and Dc.
The developing unit of each of the process cartridges 7n, 7y, 7m, and 7c carries toner (image toner or bonding toner) serving as developer on the developing roller and supplies the toner to the corresponding one of the photosensitive drums Dn, Dy, Dm, and Dc, and thus the electrostatic latent image is developed into a toner image. To be noted, the bonding toner image formed from bonding toner on the photosensitive drum Dn is different from the toner image of image toner (normal toner image) for printing an image such as a text or a figure on the sheet Pin that the bonding toner image is not aimed at conveying visual information. However, in the description below, the bonding toner image developed by an electrophotographic process to form a bonding toner image in a predetermined pattern on the sheet P will be also treated as one kind of “toner image”.
The toner images formed in the process cartridges 7n, 7y, 7m, and 7c are transferred from the photosensitive drums Dn, Dy, Dm, and Dc onto the transfer belt 3a through primary transfer respectively by electric fields formed between the photosensitive drums Dn, Dy, Dm, and Dc and the primary transfer rollers Fn, Fy, Fm, and Fc. The toner image borne on the transfer belt 3a and having reached the transfer nip 5n is transferred onto the sheet P fed and conveyed from the cassette 8 thereto, through secondary transfer by an electric field formed between the secondary transfer roller 5 and the secondary transfer opposing roller 3b.
Then, the sheet P is conveyed to the fixing unit 6 and subjected to a thermal fixation process. That is, when the sheet P passes through the fixing nip 6n, the toner image on the sheet P is heated and pressurized, and thus the image toner and the bonding toner melt. Then, the molten toner solidifies and adheres, and thus the toner image is fixed to the sheet P.
A reverse conveyance flap 21 is disposed downstream of the fixing nip 6n in the sheet conveyance direction. The reverse conveyance flap 21 is a guide member for switching the conveyance path of the sheet P on the basis of a simplex/duplex setting designated in the print instruction.
In the case of a simplex mode (simplex printing) in which a toner image is formed on only one surface of the sheet P, the reverse conveyance flap 21 guides the sheet P toward a discharge roller pair 22. In the case of a duplex mode (duplex printing) in which an image is formed on each surface of the sheet P, the reverse conveyance flap 21 guides the sheet P on a front surface of which a toner image has been formed toward a reverse conveyance roller pair 23 (switchback roller pair). The reverse conveyance roller pair 23 performs switchback in which the sheet P is conveyed in a second direction opposite to a first direction after the sheet P is conveyed in the first direction and before the trailing end of the sheet P passes a nip portion of the reverse conveyance roller pair 23. The sheet P switched back by the conveyance roller pair 23 is conveyed through a duplex conveyance path 27 to pass through the transfer nip 5n and the fixing nip on again, and thus a toner image is formed on a back surface thereof. The sheet P on the back surface of which a toner image has been formed is guided toward the discharge roller pair 22 by the reverse conveyance flap 21.
The discharge roller pair 22 discharges the sheet P to the outside of the printer portion 1. As a result of this, the image forming operation on one sheet P is completed. In the present embodiment, the sheet P discharged from the discharge roller pair 22 is received by an intermediate conveyance unit 26. The intermediate conveyance unit 26 conveys the sheet P toward the post-processing apparatus 4 by conveyance roller pairs 24 and 25.
As illustrated in
The post-processing apparatus 4 includes a conveyance path through which the sheet P received from the outside is conveyed, a plurality of conveyance roller pairs arranged along the conveyance path, a booklet making apparatus 50 that forms a booklet by bonding a plurality of sheets P together, an upper discharge tray 33, and a lower discharge tray 34.
In the present embodiment, the plurality of conveyance roller pairs include an inlet roller pair 30, a first roller pair 31, a discharge reverse conveyance roller pair 32, a second roller pair 36, a third roller pair 37, an inner discharge roller pair 38, and a booklet discharge roller pair 39. The inlet roller pair 30, the first roller pair 31, and the discharge reverse conveyance roller pair 32 are disposed on a first conveyance path extending from an inlet port through which the sheet P is received from the outside toward the upper discharge tray 33. The second roller pair 36, the third roller pair 37, and the inner discharge roller pair 38 are disposed on a second conveyance path extending from the discharge reverse conveyance roller pair 32 toward the booklet making apparatus 50. The booklet discharge roller pair 39 is disposed on a third conveyance path extending from the booklet making apparatus 50 toward the lower discharge tray 34.
The upper discharge tray 33 is a supporting portion on which sheets P not subjected to the processing by the booklet making apparatus 50 are supported. The lower discharge tray 34 is a supporting portion on which a booklet having undergone the processing by the booklet making apparatus 50 is supported. The discharge reverse conveyance roller pair 32 is a discharge portion that discharges the sheet P onto the upper discharge tray 33. In addition, the discharge reverse conveyance roller pair 32 is a reverse conveyance portion that switches back the sheet P conveyed through the first conveyance path and feeds the sheet P to the second conveyance path. The booklet discharge roller pair 39 is a discharge portion that discharges the booklet conveyed thereto through a third conveyance path. To be noted, the casing of the post-processing apparatus 4 is provided with a discharge port through which the sheet P is discharged toward the upper discharge tray 33, and a booklet discharge port 40 through which the booklet is discharged toward the lower discharge tray 34.
The operation of the post-processing apparatus 4 will be described. The sheet P conveyed from the intermediate conveyance unit 26 is conveyed to the discharge reverse conveyance roller pair 32 through the inlet roller pair 30 and the first roller pair 31. In the case where not performing the bonding process on the sheet P (not forming the booklet) is set in the print instruction, the sheet P is discharged straight onto the upper discharge tray 33 by the discharge reverse conveyance roller pair 32, and is supported on the upper discharge tray 33.
In the case where performing the bonding process on the sheet P (forming the booklet) is set in the print instruction, the sheet P is switched back by the discharge reverse conveyance roller pair 32. That is, the discharge reverse conveyance roller pair 32 conveys the sheet P in the first direction (discharge direction), and when the trailing end of the sheet P in the first direction passes a reverse conveyance flap 35, the sheet conveyance direction is reversed to a second direction opposite to the first direction, and the sheet P is fed into the second conveyance path. The sheet P passes through the second roller pair 36 and the third roller pair 37, and is discharged to the booklet making apparatus 50 by the inner discharge roller pair 38.
The booklet making apparatus 50 forms a booklet by bonding a plurality of sheets P together by the bonding toner. Details of the booklet making apparatus 50 will be described later. The booklet discharge roller pair 39 discharges the booklet conveyed thereto from the booklet making apparatus 50 to the outside of the post-processing apparatus 4 through the booklet discharge port 40. The discharged booklet is supported on the lower discharge tray 34.
Next, the booklet making apparatus 50 will be described. As illustrated in
The alignment mechanism aligns the sheets conveyed to the intermediate supporting portion 51 to a position to be subjected to the heat-and-pressure bonding (bonding operation) by the heat-and-pressure bonding unit 60. The alignment method of the sheet stack by the alignment mechanism will be described with reference to
As illustrated in
As illustrated in
Next, as illustrated in
The booklet making apparatus 50 aligns each sheet P of the sheet stack supported on the intermediate supporting portion 51 in the longitudinal direction and the lateral direction as described above. The heat-and-pressure bonding unit 60 that will be described next performs heat-and-pressure bonding on the aligned sheet stack, and thus bonds the sheets together via the bonding toner.
To be noted, although a case where the sheets Pare conveyed one by one to the booklet making apparatus 50 has been described with reference to
To be noted, the mechanism that stacks the succeeding sheet on the preceding sheet (stack) while reciprocating the preceding sheet (stack) between the discharge reverse conveyance roller pair 32 and the second roller pair 36 as described above is an example of a buffering mechanism (stacking portion) that conveys a plurality of sheets toward the intermediate supporting portion 51 in a stacked state. A different known mechanism may be used as the buffering mechanism (stacking portion).
In the case where a plurality of sheets in a stacked state is conveyed to the booklet making apparatus 50, the alignment mechanism of the booklet making apparatus 50 can perform the alignment operation as follows. When stacking the plurality of sheets P, the sheets are offset from each other such that a lower sheet P projects more downstream in the longitudinal direction (more toward the longitudinal alignment standard plates 52) than a higher sheet P on the intermediate supporting portion 51. When the trailing end of the lowermost sheet P passes the inner discharge roller pair 38, the longitudinal alignment roller 53 moves the lowermost sheet P in the longitudinal direction to cause the lowermost sheet P to abut the longitudinal alignment standard plates 52. Similarly, each time the trailing end of one upper sheet P passes the inner discharge roller pair 38, the longitudinal alignment roller 53 moves that sheet P in the longitudinal direction and causes the sheet Pto abut the longitudinal alignment standard plates 52. As a result of this, the positions of the plurality of sheets P in the longitudinal direction are aligned. After the positions of the plurality of sheets P in the longitudinal direction are aligned, the lateral alignment claws 54 move the plurality of sheets P toward the lateral alignment standard plates 55, and causes the plurality of sheets P to collectively abut the lateral alignment standard plates 55. As a result of this, the positions of the plurality of sheets P in the lateral direction are aligned.
The heat-and-pressure bonding unit 60 of the booklet making apparatus 50 will be described.
The heat-and-pressure bonding unit 60 is an example of a bonding portion that bonds sheets together. The heat-and-pressure bonding unit 60 includes a pressurizing plate 62, a receiving plate 67, a heater 70, a heater support body 63, a metal stay 66, and a pressurizing lever 65. The pressurizing plate 62 is an example of a pressurizing member (first pressurizing member or heating pressurizing member) that pressurizes the sheet P. The receiving plate 67 is an example of a receiving member (second pressurizing member) that receives the pressurizing force of the pressurizing plate 62 and pressurizes the sheets P together with the pressurizing plate 62. The heater 70 is an example of a heating portion (heat source) that heats the pressurizing plate 62.
As the heater 70, a ceramic heater in which heat-generating resistor 72 is formed on a ceramic substrate 71 can be used. The substrate 71 has, for example, a plate shape having a thickness of 1.0 mm. The pressurizing plate 62 is caused to abut a lower surface (surface on the lower side in the drawing) of the heater 70. The pressurizing plate 62 is, for example, a plate member formed from aluminum and having a thickness of 1.5 mm. By designing the heater 70 and the pressurizing plate 62 to have a lower heat capacity in this manner, the power consumption of the heat-and-pressure bonding unit 60 can be reduced. To be noted, for the substrate 71 of the heater 70, a material of high rigidity other than ceramics, such as metal, can be also used.
For the pressurizing plate 62, a material having a low heat capacity and high thermal conductivity for transmitting the heat from the heat source to the sheet P efficiently is suitable. For the pressurizing plate 62, a material having an elastic modulus of 1000 Pa or more at which deformation by pressurizing force during heat-and-pressure bonding is suitable, and preferably a material of a high elastic modulus of 10000 Pa or more is used.
The heater 70 generates heat in response to power supply to the heat-generating resistor 72. A controller provided in the post-processing apparatus 4 controls the power input to the heat-generating resistor 72 on the basis of the temperature detected by a thermistor 64 serving as a temperature detection portion, and thus the pressurizing plate 62 is controlled to a predetermined target temperature suitable for heat-and-pressure bonding of the sheets P. The thermistor 64 of the present embodiment is supported by the heater support body 63, and is in contact with the upper surface of the heater 70 (back surface of the surface of the heater 70 opposing the pressurizing plate 62).
The heater support body 63 supports the heater 70. The heater support body 63 is formed from a material such as liquid crystal polymer that is one of high-heat resistance functional resins. The heater support body 63 is supported by the metal stay 66. The pressurizing plate 62, the heater 70, the heater support body 63, and the metal stay 66 are a movable unit (heater unit) that reciprocates in the Z direction so as to come closer to and away from the receiving plate 67. The metal stay 66 is a reinforcing member (rigid member) that improves the rigidity of the movable unit.
The pressurizing lever 65 is fastened to the metal stay 66, and reciprocates in the Z direction by the driving force of a drive source. As a result of the pressurizing lever 65 moving down the movable unit, the pressurizing plate 62 comes into contact with the uppermost sheet of the sheet stack on the receiving plate 67. In addition, as a result of the pressurizing lever 65 moving up the movable unit, the pressurizing plate 62 moves away (retracts) from the sheet stack on the receiving plate 67.
The receiving plate 67 is, for example, a member formed from silicone rubber and having a plate shape of a thickness of 2.0 mm, and is supported by the frame body of the booklet making apparatus 50 (frame body of the post-processing apparatus 4). The receiving plate 67 has a role of applying a consistent pressurizing force to the sheet stack by receiving the sheet stack pressed by the pressurizing lever 65.
The material of the receiving plate 67 is not limited to silicone rubber. For stably transmitting the pressurizing force to the sheet stack, it is preferable that the material of the receiving plate 67 has an elastic modulus of 1000 Pa or less, which is a value corresponding to deformability of a certain degree, is strong against repeated stress, and is heat-resistant.
The heat-and-pressure bonding unit 60 performs the heat-and-pressure bonding operation (bonding operation) of pressurizing and heating the sheet stack by the pressurizing plate 62. Specifically, in the heat-and-pressure bonding operation, after the pressurizing plate 62 in a state of being heated up to the target temperature in advance is brought into pressure contact with the sheet stack for a predetermined period (for example, 2 seconds), and then the pressurizing plate 62 is separated from the sheet stack. The sheet stack is pressurized by being nipped between the pressurizing plate 62 and the receiving plate 67, and is heated by the pressurizing plate 62 heated by the heat from the heater 70. As a result of the heat-and-pressure bonding operation, the bonding toner applied in the printer portion 1 in advance softens, and thus the sheets are bonded together via the bonding toner serving as an adhesive.
The booklet making apparatus 50 of the present embodiment performs the heat-and-pressure bonding operation once by the heat-and-pressure bonding unit 60 each time a predetermined number of sheets P are stacked, and thus forms a booklet as a product including sheets of a number larger than the predetermined number. That is, the heat-and-pressure bonding unit 60 performs the next heat-and-pressure bonding operation in a state in which a succeeding sheet is stacked on a bonded sheet stack that has been bonded by the previous heat-and-pressure bonding operation, and thus bonds a surface (first surface) of the uppermost sheet of the bonded sheet stack to a surface (second surface) of the succeeding sheet opposing the first surface. As a result of this, the heat-and-pressure bonding unit 60 can form a booklet of a sheet number larger than the number of sheets that can be bonded in one heat-and-pressure bonding operation.
The number (predetermined number) of sheets P subjected to heat-and-pressure bonding in one heat-and-pressure bonding operation by the heat-and-pressure bonding unit 60 can be appropriately changed in consideration of the time required for the heat-and-pressure bonding process and the productivity of the booklet formation. The heat-and-pressure bonding unit 60 may be configured to perform the heat-and-pressure bonding operation once each time one succeeding sheet is stacked on the bonded sheet stack. In the description below, description will be given on the premise that the heat-and-pressure bonding unit 60 performs the heat-and-pressure bonding operation once each time five sheets P are stacked on the intermediate supporting portion 51.
For example, a booklet constituted by fifty sheets P is formed by the following process.
To be noted, in the case where sheets P stacked in the buffering mechanism (stacking portion) in advance are conveyed to the booklet making apparatus 50, the number of sheets P stacked in the buffering mechanism (stacking portion) is set to be equal to the number of sheets P subjected to heat-and-pressure bonding by the heat-and-pressure bonding unit 60 by one heat-and-pressure bonding operation. As a result of this, the time required for completing the alignment of a predetermined number of sheets P can be shortened, and thus the interval of the heat-and-pressure bonding operation can be shortened in some case as compared with the case where the booklet making apparatus 50 aligns one by one a plurality of number of sheets P conveyed thereto one by one. Further, the overall productivity of the post-processing apparatus 4 can be improved.
In addition, in the case where the number of sheets included in one copy of booklet is smaller than the predetermined number, the heat-and-pressure bonding operation may be performed when all the sheets P included in one copy of booklet are supported on the intermediate supporting portion 51 and aligned by the alignment mechanism.
The booklet formed by the heat-and-pressure bonding operation by the heat-and-pressure bonding unit 60 is pushed out toward the booklet discharge port 40 (
The positional relationship between the sheet P and the heater 70 of the heat-and-pressure bonding unit 60 in the booklet making apparatus 50 will be described with reference to
In the present embodiment, the position of the longitudinal alignment standard plates 52 and the position of the lateral alignment standard plates 55 are fixed to preset positions regardless of the size of the sheet P. That is, the standard position in the X direction and the standard position in the Y direction during sheet alignment in the booklet making apparatus 50 are constant regardless of the size of the sheet P.
The heat-and-pressure bonding unit 60 is disposed such that an end portion on the same side as the lateral alignment standard plates 55 of the sheet P can be subjected to heat-and-pressure bonding with respect to the position of the longitudinal alignment standard plates 52 and the position of the lateral alignment standard plates 55. The heater 70 of the present embodiment extends in the X direction from the position of the longitudinal alignment standard plates 52 to a length including the long-side length (297 mm) of the A4 size, and is positioned at a predetermined position with respect to the lateral alignment standard plates 55. As described above, by setting the position and size of the heater 70 with respect to the position of the longitudinal alignment standard plates 52 and the position of the lateral alignment standard plates 55, sheets of various sizes can be more reliably bonded.
Examples of the bonding mode for different application patterns of bonding toner Tn will be described with reference to
In the case of forming a booklet including n sheets P, the printer portion 1 applies the bonding toner Tn in a predetermined bonding region (bonding portion) on each surface of each sheet P excluding the front surface of the first sheet P serving as the front cover of the booklet and the back surface of the n-th sheet P serving as the back cover of the booklet. Further, the booklet making apparatus 50 of the post-processing apparatus 4 forms a booklet in which n sheets P are bonded by repeatedly performing the heat-and-pressure bonding operation by the heat-and-pressure bonding unit 60 each time a predetermined number of sheets P are stacked.
To be noted, although an example in which the bonding toner Tn is applied on each surface of each sheet P has been described herein, a configuration in which the bonding toner Tn is applied on only one surface of each sheet P may be employed. Normally, applying the bonding toner Tn on both surfaces of the sheet P makes the bonding stronger because the sheets are bonded via a sufficient amount of the bonding toner Tn.
Whether the bonding toner Tn is applied on one surface or two surfaces may be appropriately selected in consideration of the performance of the booklet making apparatus 50, the type of the bonding toner Tn or the sheet P, the function desired for the booklet, and the like. For example, in the case of a booklet to be preserved or in the case of using a cardboard or a special sheet P for the front cover or the back cover of the booklet, the bonding toner Tn may be applied on each surface of the sheet P to obtain more reliable adhesion. In the case of a booklet for simple primary use, a configuration in which the bonding toner Tn is applied on only one surface of the sheet P may be employed.
As illustrated in
The bonding force of 0.5 N/cm obtained by the studying of this time is confirmed by using a plain paper sheet Office 70 (70 g) available from Canon Marketing Japan Inc. as the sheet P. Although the bonding force described above was confirmed by using several types of sheets P, since the standard for sufficient bonding force can change depending on the type of the sheet and the use of the product, the bonding force may be evaluated by using a value different from 0.5 N/cm as a standard.
As illustrated in
Next, a phenomenon that occurs when forming the booklet will be described. As described above, by applying the bonding toner Tn on opposing surfaces of sheets to be bonded together, the bonding force can be enhanced as compared with a case where the bonding toner Tn is applied on only one surface of each sheet. However, in the case of forming a booklet serving as one copy of booklet by repeating the heating and pressurization by the pressurizing plate 62, the pressurizing plate 62 comes into contact with the bonding toner Tn applied on a surface of the sheet stack (provisional booklet) in the middle of the formation of the booklet, and part of the bonding toner Tn can attach to the pressurizing plate 62. Further, there is a possibility that the bonding toner Tn transfers from the pressurizing plate 62 to a sheet serving as the front cover or the back cover of the booklet to stain the sheet, and thus the quality of the complete booklet is degraded.
Specific description will be given with reference to
In the description below, similarly, a new provisional booklet is formed as a result of the pressurizing plate 62 heating and pressurizing an already bonded provisional booklet and succeeding sheets stacked on the provisional booklet.
Here, when forming a provisional booklet, the bonding toner Tn is applied on the front surface of the uppermost sheet of the provisional booklet. Specifically, as illustrated in
Therefore, as illustrated in
The bonding toner Tn attached to the pressurizing plate 62 comes into contact with the front surface P10a (
However, in the final heat-and-pressure bonding operation, the pressurizing plate 62 comes int contact with the front surface P50a (
As described above, there is a possibility that the bonding toner Tn attached to the pressurizing plate 62 in the heat-and-pressure bonding operations during the formation of the booklet attaches to a sheet serving as an outer surface (front cover or back cover) of the complete booklet in the final heat-and-pressure bonding operation and the quality of the booklet is degraded.
In the case of using colored toner similar to the image toner as the bonding toner Tn, the bonding toner Tn transferred onto the outer surface of the complete booklet is visualized as colored stain. In addition, also in the case of using colorless or white toner as the bonding toner Tn, there is a case where the stain is visualized as a result of the bonding toner Tn solidifying in a state in which foreign matter such as paper dust and dust is mixed in the bonding toner Tn or as a result of gloss difference from the surrounding regions.
Incidentally, the attachment of toner to the pressurizing plate 62 can be avoided if the bonding toner Tn is not applied on the front surface P5a of the fifth sheet P5, the front surface P10a of the tenth sheet P10, and the like that the pressurizing plate 62 comes into contact with. However, since the bonding force is reduced by reducing the amount of the bonding toner Tn, there is a possibility that the bonding force is insufficient for, for example, the fifth and sixth sheets P5 and P6.
In addition, increasing the toner amount of the bonding toner Tn on the back surface P6b of the sixth sheet P6 to obtain sufficient bonding force without applying the bonding toner Tn on the front surface P5a of the fifth sheet P5 can be also considered. For example, applying the bonding toner Tn at a toner amount of 0.3 mg/cm2 on other sheets and applying the bonding toner Tn at a toner amount of 0.6 mg/cm2, which is a double value, on the back surface P6b of the sixth sheet P6 can be considered.
However, there is a case where it is difficult to develop a toner image by a toner amount of 0.6 mg/cm2 by a single process cartridge 7n. In addition, although superimposing toner images developed by a plurality of cartridges on the sheet P to increase the toner amount can be considered, this requires providing a plurality of process cartridges 7n using the bonding toner, which can lead to increase in the size and complexity of the image forming apparatus 1S.
Therefore, in the present embodiment, the toner amount of the bonding toner Tn applied on a surface (first surface) of a sheet P that comes into contact with the pressurizing plate 62 during the formation of the booklet is set to be smaller than the toner amount of the bonding toner Tn applied on a surface (second surface) of a sheet P opposing the first surface. In other words, in the present embodiment, the amount of the bonding toner applied on the first surface by the image forming portion is smaller than the amount of the bonding toner applied on the second surface by the image forming portion. More specifically, the amount (unit: mg/cm2) of the bonding toner applied on the first surface by the image forming portion per unit area of the first surface is smaller than the amount of the bonding toner applied on the second surface of the image forming portion per unit area of the second surface. The first surface mentioned herein is a surface of the uppermost sheet of the bonded sheet stack bonded by the previous bonding operation, and the second surface is a surface of a succeeding sheet to be bonded to the first surface. According to this configuration, the possibility of the bonding toner Tn attached to the pressurizing plate 62 in the heat-and-pressure bonding operation during the formation of the booklet staining the complete booklet can be lowered.
The influence of change in the amount of the bonding toner Tn applied on surfaces (opposing surfaces) opposing each other of two sheets P to be bonded together on the bonding force was checked.
As illustrated in
Therefore, it is preferable that the amount of the bonding toner Tn applied on the surface (second surface) of the sheet P opposing the first surface is increased while reducing the amount of the bonding toner Tn applied on the surface (first surface) of the sheet P that comes into contact with the pressurizing plate 62 during the formation of the booklet. Specifically, it is preferable that the sum of amounts of the bonding toner Tn applied on the first surface and the second surface is approximately equal to or larger than the sum of amounts of the bonding toner Tn applied on the opposing surfaces of the sheets P that do not come into contact with the pressurizing plate 62. In the present embodiment, since 0.3 mg/cm2 of the bonding toner Tn is applied on each of the opposing surfaces of the sheets P that do not come into contact with the pressurizing plate 62, it is preferable that the sum of the amounts of the bonding toner Tn applied on the first surface and the second surface is also set to 0.6 mg/cm2. In other words, the sum of the amount of the bonding toner applied on the first surface and the amount of the bonding toner applied on the second surface is 0.6 mg/cm2 or more in the present embodiment. In addition, the sum of amounts of the bonding toner applied on opposing surfaces of two adjacent sheets in the product other than the first surface and the second surface is 0.6 mg/cm2 or more.
In addition, when reducing the amount of the bonding toner Tn on the first surface and increasing the amount of the bonding toner Tn on the second surface, it is preferable that the sheets P are bonded together by a sufficient bonding force. That is, it is preferable that the bonding force between the sheets by which the first surface and the second surface are bonded is 0.5 N/cm or more. In addition, it is preferable that the bonding force by which the opposing surfaces of two adjacent sheets in the product other than the first surface and the second surface are bonded is 0.5 N/cm or more. By setting the amount of the bonding toner applied on each sheet by the printer portion 1 in accordance with the characteristics of the bonding toner Tn such that such bonding force can be obtained, sufficient bonding force can be obtained for the booklet serving as a product.
To be noted, as described above, there is an upper limit in the toner amount of the toner image that can be developed by the single process cartridge 7n. In the process cartridge 7n of the present embodiment, the upper limit is about 0.5 mg/cm2. In this case, the sum of the amounts of the bonding toner Tn applied on the first surface and the second surface is set to 0.6 mg/cm2 while setting the amount of the bonding toner Tn applied on the second surface is set to 0.5 mg/cm2 or less. As a result of this, the possibility of the bonding toner Tn attached to the pressurizing plate 62 in the heat-and-pressure bonding operation during the formation of the booklet staining the complete booklet can be lowered while avoiding the increase in the size and complexity of the image forming apparatus 1S.
The upper limit of the toner amount of the toner image that can be developed by the single process cartridge 7n can change depending on various conditions related to the developing step. Examples of these conditions include the types and outer diameters of the photosensitive drums, developing rollers, developing blades, and the like, the nature of the toner, the potential of the electrostatic latent image formed on the photosensitive drum, and potential settings of the photosensitive drum, developing roller, and developing blade. In addition, 0.5 mg/cm2 that has been described as an example of the upper limit of the toner amount has been described as a value of the toner amount that can be used regardless of conditions varying for each user such as the use environment and use status of the image forming apparatus 1S and the sheet to be used.
Next, whether the complete booklet is stained was checked while changing the amounts of the bonding toner Tn applied on the surface (first surface) of the sheet P that comes into contact with the pressurizing plate 62 during the formation of the booklet and the surface (second surface) of the sheet P opposing the first surface.
The horizontal axis of
What the symbols in
In addition, in
As illustrated in
In addition, it was confirmed that a sufficient bonding force can be obtained while reducing the stain on the booklet by setting the amounts M1 and M2 of the bonding toner Tn such that the sum of M1 and M2 is about 0.6 mg/cm2 or more while maintaining the relationship of M1<M2. To be noted, since the standard for the sufficient bonding force can change in accordance with the application of the product as described above, at least a product on which stain is reduced can be obtained by the relationship of M1<M2 even if the sum of M1 and M2 is about 0.6 mg/cm2.
In contrast, it was confirmed that toner attachment to the back cover of the booklet becomes more likely to occur if the toner amount M1 on the front surface of the 5n-th sheet P is set to be larger than the toner amount M2 on the back surface of the (5n+1)-th sheet P that is a surface opposing thereto (M1>M2). In addition, although a sufficient bonding force can be obtained by setting the amounts M1 and M2 of the bonding toner Tn such that the sum of M1 and M2 is about 0.6 mg/cm2 or more, there was a case (×) that a stain that was easily visually recognizable was attached to the back cover of the complete booklet.
From the results described above, it can be seen that it is preferable that the toner amount M1 on the front surface of the 5n−th sheet P that comes into contact with the pressurizing plate 62 during the formation of the booklet is set to, for example, 0.2 mg/cm2, and the toner amount M2 on the back surface of the (5n+1)-th sheet P serving as the opposing surface is set to, for example, 0.4 mg/cm2. As a result of this, sufficient bonding force can be obtained while reducing the stain on the booklet.
As described above, the bonding portion of the present embodiment bonds the first surface of the uppermost sheet of the bonded sheet stack and the second surface of the succeeding sheet opposing the first surface are bonded by performing the next bonding operation in a state in which the succeeding sheet is stacked on the bonded sheet stack bonded in the previous bonding operation. As a result of this, a product in which sheets of a sheet number larger than the number of sheets that can be bonded in one bonding operation can be formed.
Further, the amount of the bonding toner applied on the first surface by the image forming portion is smaller than the amount of the bonding toner applied on the second surface by the image forming portion. As a result of this, attachment of the bonding toner to the heating pressurizing member in a bonding operation during the formation of the product can be suppressed, and the possibility of the bonding toner attached to the heating pressurizing member transferring onto the outer surface of the product and staining the outer surface in the final bonding operation can be lowered.
As described above, in the present embodiment, the amount of the bonding toner applied on the first surface of the sheet and the amount of the bonding toner applied on the second surface of the succeeding sheet to be bonded to the first surface can be changed to reduce the stain on the product. That is, according to the present embodiment, the toner amount at the bonded portion can be changed as necessary. That is, according to the present embodiment, an image forming apparatus capable of improving the quality of the sheet stack can be provided.
In the first embodiment, the amount of the bonding toner Tn applied on the surfaces of the sheet P other than the surface (first surface) of the sheet P that comes into contact with the pressurizing plate 62 during the formation of the booklet and the surface (second surface) of the sheet P opposing the first surface is constant (for example, 0.3 mg/cm2). As a modification example, the amount of the bonding toner Tn applied on the front surface that is a surface opposing the pressurizing plate 62 may be set to be smaller than the amount of the bonding toner Tn applied on the back surface that is a surface not opposing the pressurizing plate 62 for all the sheets P included in the complete booklet. Here, the “surface opposing the pressurizing plate 62” is a surface where each sheet P opposes the pressurizing plate 62 in
In other words, in the present modification example, the amount of the bonding toner applied on the surface opposing the pressurizing member of each sheet by the image forming portion is smaller than the amount of the bonding toner applied on the surface on the side opposite to the surface opposing the pressurizing member of each sheet by the image forming portion. That is, the amount of the bonding toner applied on the opposing surface opposing the pressurizing member of each sheet by the image forming portion per unit area of the opposing surface is smaller than the amount of the bonding toner applied on an opposite surface that is on the opposite side to the opposing surface of each sheet by the image forming portion per unit area of the opposite surface. According to the present modification example, the toner amount at the bonded portion can be changed as necessary.
Since the amount of the bonding toner Tn on the front surface of each sheet P is smaller than the amount of the bonding toner Tn on the back surface, the amount of the bonding toner Tn on the surface (first surface) of the sheet P that comes into contact with the pressurizing plate 62 during the formation of the booklet is also smaller than the amount of the bonding toner Tn on the surface (second surface) of the sheet P opposing the first surface. Therefore, also in the present modification example, the stain on the complete booklet can be reduced similarly to the first embodiment.
In addition, the following advantages unique to the present modification can be also obtained. The sheet P used for the formation of the booklet is, in most cases, sheets P accommodated in the cassette 8 of the printer portion 1, and the temperature of the sheet P at the start of the image forming operation is a temperature close to the temperature (room temperature) of the installation environment in which the printer portion 1 is placed. After the toner images of the image toner and the bonding toner are transferred onto the sheet P configured in this manner, the fixing step is performed in the fixing unit 6, and thus the temperature of the sheet P increases. In the fixing step, heat necessary for melting the toner image, which varies depending on the type and amount of the toner, is applied to the sheet P. Therefore, in the fixing step, the temperature of the sheet P increases from the temperature close to the room temperature to a temperature of 80° C. to 120° C. The sheet P can curl when the temperature of the sheet P quickly increases in the fixing step as described above.
The mechanism of occurrence of the curl will be described. The sheet P contains moisture, and the amount of moisture varies depending on the temperature and humidity of the installation environment of the printer portion 1 and the material of the sheet P. Part of the moisture contained in the sheet P evaporates as vapor in the fixing step. However, the amount of the evaporating moisture differs between the front surface and the back surface of the sheet P. The curl of the sheet P is a phenomenon in which as a result of the difference in the amount of the evaporating moisture therebetween, the contraction amount of the front surface and the contraction amount of the back surface of the sheet P are different, and thus the sheet P curls such that the surface with the larger contraction amount is on the inside.
In the fixing step on the front surface of the sheet P, the temperature of the sheet P quickly increases from the temperature close to the room temperature to the temperature for the fixation, and therefore the difference in the amount of evaporating moisture between the front surface and the back surface of the sheet P is likely to be large. That is, the curl tends to be large in the fixing step on the front surface of the sheet P.
When the amount of the bonding toner Tn applied on the front surface of the sheet P is reduced, it becomes easier to obtain sufficient fixation even if the heat applied to the sheet Pin the fixing step on the front surface of the sheet P is reduced. Therefore, by reducing the heat applied to the sheet P in the fixing step on the front surface of the sheet P, the occurrence of the curl can be suppressed.
In contrast, in the fixing step on the back surface of the sheet P, the amount of moisture in the sheet P has been reduced in the fixing step on the front surface and the amount of newly evaporating moisture is small, and therefore the difference in the amount of evaporating moisture between the front surface and the back surface of the sheet P is small. In addition, since the temperature of the sheet P has increased to some extent in the fixing step on the front surface, the heat applied to the sheet P in the fixing step on the back surface may be smaller than in the fixing step on the front surface. Therefore, a large curl is not likely to occur even if the amount of the bonding toner Tn applied on the back surface of the sheet P is increased.
As described above, in the present modification example, the occurrence of the curl can be suppressed by setting the amount of the bonding toner Tn applied on the front surface to be smaller than the amount of the bonding toner Tn applied on the back surface for all the sheets P included in the complete booklet. As a result of this, the alignment of the sheets P in the booklet making apparatus 50 becomes easier, and thus a booklet having good alignment between the sheets can be formed.
To be noted, although formation of the booklet by edge bonding (long-side binding) of sheets has been mainly described in the first embodiment, an effect similar to the first embodiment can be also obtained in the case of forming the booklet by corner bonding (corner binding) of sheets.
In addition, in the first embodiment, an example in which the surface of the sheet on which the toner image is formed earlier in the printer portion 1 serves as the surface opposing the pressurizing plate 62 in the booklet making apparatus 50 and the surface on which the toner image is formed later serves as the surface not opposing the pressurizing plate 62 in the booklet making apparatus 50 has been described. However, a configuration in which the surface of the sheet on which the toner image is formed earlier in the printer portion 1 serves as the surface not opposing the pressurizing plate 62 in the booklet making apparatus 50 and the surface on which the toner image is formed later serves as the surface opposing the pressurizing plate 62 in the booklet making apparatus 50 may be employed. Also in this case, an effect similar to the first embodiment can be obtained by setting the amount of the bonding toner Tn applied on the surface (first surface) of the sheet that comes into contact with the pressurizing plate 62 to be smaller than the amount of the bonding toner Tn applied on the surface (second surface) of the sheet opposing the first surface.
In addition, in the first embodiment and each modification example described above, the configuration in which “the amount of the bonding toner applied on the first surface by the image forming portion is smaller than the amount of the bonding toner applied on the second surface by the image forming portion” is realized by the difference in the amount of the bonding toner per unit area, but the configuration is not limited to this, and for example, the thickness of the layer of the bonding toner applied on the first surface by the image forming portion may be set to be smaller than the thickness of the layer of the bonding toner applied on the second surface by the image forming portion. Alternatively, the toner density of the layer of the bonding toner formed on the first surface by the image forming portion may be set to be lower than the toner density of the layer of the bonding toner formed on the second surface by the image forming portion. For example, the image coverage (ratio of an area covered by the bonding toner to the area of the bonding region) in the bonding region on the first surface is set to be lower than the image coverage in the bonding region on the second surface to be bonded to the bonding region on the first surface. In addition, in the case where the bonding toner is a colored toner including colorant, the “density” may be optical density. A similar effect to the first embodiment can be also obtained by these modification examples.
As a second embodiment, a configuration in which one type of toner is used as both the image toner and the bonding toner will be described. By using one type of toner as both the image toner and the bonding toner, the sheet bonding function can be relatively easily imparted by using the configuration of a monochromatic image forming apparatus. In addition, in the second embodiment, a configuration in which different toner amounts are set for the image region and the bonding region on the sheet will be described. To be noted, also in the first embodiment, the bonding toner Tn may be colored black, and the black color may be expressed by the bonding toner Tn instead of the process black. In this case, not only a sheet bonding function can be imparted by still using the configuration of a color image forming apparatus, but also the amount of toner consumption when expressing black can be reduced.
In the description below, it is assumed that elements denoted by the same reference signs as in the first embodiment have substantially the same configuration and function as those described in the first embodiment unless otherwise described, and parts different from the first embodiment will be mainly described.
The image forming unit 1e of the present embodiment is an electrophotographic unit of a direct transfer system including one process cartridge 7n (enclosed by a thick broken line), a scanner unit 2, and a transfer unit 208 (transfer roller). The process cartridge 7n includes a photosensitive drum Dn serving as an image bearing member, a charging roller 201, and a developing unit. The charging roller 201 functions as a charging portion that charges the photosensitive drum Dn. The developing unit includes a toner accommodating portion 202 accommodating toner Tnbk serving as developer, a developing roller 205 serving as a developer bearing member that bears the toner, and a supply member 204 that supplies the toner to the developing roller 205. The developing unit further includes an agitating member 203 that agitates the toner Tnbk, and a regulating member 206 (developing blade) that regulates the amount of the toner Tnbk borne on the developing roller 205.
The process cartridge 7n forms a visible image by using the colored toner Tnbk, and forms a toner image for applying the toner Tnbk in a predetermined bonding pattern on the sheet P. In the present embodiment, the toner Tnbk is colored black. The toner image formed on the photosensitive drum Dn in the process cartridge 7n is transferred from the photosensitive drum Dn onto the sheet P in a transfer nip 5n by the transfer unit 208.
To be noted, three process cartridges of yellow, magenta, and cyan may be provided in addition to the black process cartridge 7n to form a color image forming apparatus. In addition, the yellow toner may be used as the bonding toner. In this case, the application region of the bonding toner becomes less visually recognizable, and thus the texture of the product can be improved. The configuration is not limited to this, and the types and number of the toner can be changed in accordance with the application of the image forming apparatus 200S.
In the process cartridge 7n, the photosensitive drum Dn, the charging roller 201, and the developing unit may be disposed in one unit. In addition, in the process cartridge 7n, for example, the photosensitive drum Dn and the charging roller 201 may be disposed in a unit (drum unit) different from the developing unit, and each unit may be individually attachable to and detachable from a casing 19.
In the present embodiment, when a print instruction including image data is input, a controller 107 that will be described later causes the image forming unit 1e to form a toner image (hereinafter referred to as a normal image) based on the image data in a predetermined region on the sheet P. In addition, in the case where the print instruction includes a setting to form a product in which sheets P are bonded together in the booklet making apparatus 50, the controller 107 adds additional data for applying the toner Tnbk in a predetermined bonding pattern on the sheet P to the image data. Then, the controller 107 causes the image forming unit 1e to form a toner image (hereinafter referred to as a bonding toner image) based on the additional data.
In the description below, a region on the photosensitive drum Dn in which a toner image for forming a normal image on the sheet P is formed will be referred to as an “image region”. In addition, a region on the photosensitive drum Dn in which a toner image for forming a bonding toner image on the sheet P is formed will be referred to as a “bonding region”. In the present embodiment, the image region and the bonding region are regions separate from each other in the main scanning direction of the scanner unit 2. That is, the bonding toner of the present embodiment is the same as the toner used for forming an image in the image region. In addition, the image forming portion of the present embodiment forms the bonding toner image in the bonding region on the sheet by using the toner, and forms an image in the image region different from the bonding region on the sheet by using the toner. In addition, in the description below, a region on the sheet P corresponding to the image region on the photosensitive drum Dn will be also referred to as an “image region” of the sheet P, and a region on the sheet P corresponding to the bonding region on the photosensitive drum Dn will be also referred to as a “bonding region” of the sheet P.
A laser driving circuit incorporated in the scanner unit 2 will be described.
The scanner unit 2 is an example of an exposing portion that forms an electrostatic latent image by performing exposure by irradiating the photosensitive drum Dn with light. The scanner unit 2 includes a semiconductor laser 100 serving as a light source, a polygonal mirror 101, a synchronization sensor 102, and the laser driving circuit 207. The laser driving circuit 207 includes a light emission control portion 103, a driving current generation portion 104, and a correction current generation portion 105.
A CPU 106 of the present embodiment performs serial communication with the driving current generation portion 104 and the correction current generation portion 105 via a serial communication signal 110. The driving current generation portion 104 outputs a laser driving current amount signal 111 on the basis of information transmitted from the CPU 106, and controls the current amount of the laser driving current 112. The correction current generation portion 105 outputs, in synchronization with a main scanning synchronization signal 108, a correction current amount signal 113 on the basis of the current amount information in a main scanning position transmitted from the CPU 106. The laser driving current 112 is controlled to a current amount obtained by subtracting a current amount based on the correction current amount signal 113 from a current amount based on the laser driving current amount signal 111.
Therefore, in the present embodiment, the amount of light radiated from the scanner unit 2 onto the photosensitive drum Dn changes in accordance with the position in the main scanning direction.
In addition, an image signal 109 transmitted from the controller 107 is generated on the basis of data obtained by adding the additional data for generating the bonding toner image to the data for generating the normal image (image data input together with the print instruction).
As the toner Tnbk of the present embodiment, toner containing thermoplastic resin and colorant can be used. The resin that can be used as the thermoplastic resin is not particularly limited, and examples thereof include polyester resin, vinyl resin, acrylic resin, and styrene acrylic resin similarly to known image toners. A plurality of these resins may be included. The toner Tnbk may contain a magnetic body, a charge control agent, a wax, an external additive, and the like.
The toner Tnbk is colored black. In the case of configuring the image forming apparatus 200S as a color image forming apparatus, the toner Tnbk may be colored a different color such as yellow, magenta, cyan, or the like. In addition, in the case of using the image forming apparatus 200S as a monofunctional sheet bonding apparatus having only the bonding function and not forming the normal image, the toner Tnbk may be configured as transparent toner without coloring.
The exposure control of the scanner unit 2 will be described with reference to
While the image signal 109 is High, the laser driving current 112 flows in the semiconductor laser 100. Therefore, in the period in which the image signal 109 is High, the current of Ir flows in the semiconductor laser 100 in a section where the value of the correction current amount signal 113 is 0, and the current of (Ir-Ic) flows in the semiconductor laser 100 in a section where the value of the correction current amount signal 113 is Vc.
The section where the value of the correction current amount signal 113 is 0 corresponds to the bonding region on the photosensitive drum Dn, and the section where the value of the correction current amount signal 113 is Vc corresponds to the image region on the photosensitive drum Dn. Therefore, the exposure light amount of scanning light L3 radiated from the semiconductor laser 100 onto the photosensitive drum Dn via the polygonal mirror 101 (
As described above, the width of the bonding region can be set by the output timings of the image signal 109 and the correction current amount signal 113. In addition, by changing the voltage Vr of the laser driving current amount signal 111 and the voltage Vc of the correction current amount signal 113, the exposure light amount in the image region and the bonding region can be changed. Since the bonding toner image is formed on the back surface of the sheet P, High is output for the image signal 109 all the time in a period in which the bonding region is scanned. The exposure light amount of the scanning light L3 is a light amount Rt in the image region, and is, in the bonding region, a light amount Rr larger than the light amount Rt.
The controller 107 that outputs the image signal 109 and the correction current generation portion 105 that outputs the correction current amount signal 113 are examples of a light amount correcting portion that corrects the light amount of the scanning light L3 emitted from the exposing unit. Rr is a light amount when the region on the photosensitive drum Dn corresponding to the bonding region on the back surface (second surface) of the sheet P opposing the front surface (first surface) of the sheet P that comes into contact with the pressurizing plate 62 during the formation is scanned by the scanning light L3. Rrf is a light amount when the region on the photosensitive drum Dn corresponding to the image region on the second surface is scanned by the scanning light L3. The controller 107 of the present embodiment corrects the light amount of the scanning light L3 in accordance with the position in the main scanning direction such that Rr>Rgr is satisfied. As a result of this, the magnitude relationship of the toner amount between the bonding region and the image region (Mr<Mgr) can be realized.
As described above in the present embodiment, the toner amount (toner deposition amount) per unit area in the bonding region on the sheet and the toner amount (toner deposition amount) per unit area in the image region can be changed by changing the light amount during exposure. That is, according to the present embodiment, the toner amount at the bonded portion can be changed as necessary. As a result of this, the toner amount in the bonding region can be set independently from the image region on the basis of other indices such as the bonding force between sheets or reduction of the stain on the product while setting the toner amount such that the image density and toner consumption amount in the image region are good.
To be noted, the toner amount of an image formed on the sheet P in the case of inputting image data of a solid image (so-called black solid image) of a density of 100% to the image forming apparatus 200S is set as the standard for the toner amount in the image region.
The controller 107 that outputs the image signal 109 is an example of a light amount correcting portion that corrects the light amount of the scanning light L3 emitted from the exposing unit. Rf is a light amount when the region on the photosensitive drum Dn corresponding to the bonding region on the front surface (first surface) of the sheet P that comes into contact with the pressurizing plate 62 during the formation is scanned by the scanning light L3. Rgf is a light amount when the region on the photosensitive drum Dn corresponding to the image region on the first surface is scanned by the scanning light L3. The controller 107 of the present embodiment corrects the light amount of the scanning light L3 in accordance with the position in the main scanning direction such that Rf<Rgf is satisfied. As a result of this, the magnitude relationship of the toner amount between the bonding region and the image region (Mf<Mgf) can be realized.
In the present embodiment, the relationship of the toner amounts of the normal image and the bonding toner image formed on each of the front surface and the back surface of each sheet P will be described with reference to
Similarly to the first embodiment, a surface (upper surface) of the sheet P opposing the pressurizing plate 62 in the booklet making apparatus 50 will be referred to as a “front surface”, and a surface (surface of the sheet P not opposing the pressurizing plate 62) on the opposite side to the front surface will be referred to as a “back surface” of the sheet P. The toner amount in the image region on the front surface of the sheet P is denoted by Mgf, the toner amount in the bonding region on the front surface is denoted by Mf, the toner amount in the image region on the back surface is denoted by Mgr, and the toner amount in the bonding region on the back surface is denoted by Mr. Each toner amount is an amount of the toner Tnbk before receiving the fixing process in the fixing unit 6, and is expressed by toner weight per unit area (unit: Mg/cm2).
As in the first embodiment, as a method to make a difference between the toner amount Mf in the bonding region on the front surface and the toner amount Mr in the bonding region on the back surface, uniformly changing the toner amount in the entire region in the main scanning direction on the photosensitive drum Dn can be considered. Specifically, there are a method of increasing and decreasing the amount of toner borne on the developing roller 205 by controlling the regulating member 206 and the supply member 204, and a method of increasing and decreasing the amount of toner to be developed on the photosensitive drum Dn by controlling the peripheral speed difference between the photosensitive drum Dn and the developing roller 205. However, by these methods, not only the toner amounts Mf and Mr in the bonding region but also the toner amounts Mgf and Mgr in the image region also increase and decrease. That is, by these methods, the toner amount can increase and decrease in accordance with the sub-scanning direction of the scanner unit 2, but the toner amount cannot be changed in accordance with the position in the main scanning direction.
In the present embodiment, as described in “Exposure Control”, the exposure light amount can be changed in accordance with the position in the main scanning direction by controlling the correction current amount signal 113 output to the scanner unit 2. As a result of this, the toner amount can be changed in accordance with the position in the main scanning direction at the same position in the sub-scanning direction, that is, between the bonding region and the image region. Specifically, as illustrated in
To be noted, an example in which the toner amount Mf in the bonding region on the front surface of one sheet P is smaller than the toner amount Mr in the bonding region on the back surface has been described with reference to
In addition, for example, if Mt=0.30 (mg/cm2) is set for the toner amounts Mgf and Mgr in the image region, a high-quality image balanced in the toner density and the toner consumption amount can be obtained. To realize this toner amount Mt, the light amount Rt for scanning the photosensitive drum Dn for forming the normal images on the front surface and the back surface of the sheet P is set to be larger than the light amount Rf for scanning the photosensitive drum Dn for forming the bonding toner image on the front surface. In addition, the light amount Rt is set to be smaller than the light amount Rr for scanning the photosensitive drum Dn for forming the bonding toner image on the back surface.
Comparative Example 1 has a configuration in which only the bonding toner Tn is changed from the configuration of the first embodiment to the toner Tnbk of the second embodiment. Therefore, the exposure light amount cannot be changed in accordance with the position in the main scanning direction.
In the configurations of Comparative Example 1 and the second embodiment, a booklet including fifty sheets P was formed a plurality of times as described with reference to
The bonding force between the sheets P was measured by the same method as that described with reference to
In Comparative Example 1, the toner amount Mf in the bonding region on the front surface was set to 0.2 mg/cm2, and the toner amount Mr in the bonding region on the back surface was set to 0.4 mg/cm2. In this case, the results of the bonding force and the reduction of the toner attachment to the pressurizing plate 62 were good. However, in Comparative Example 1, since the toner amount Mgf in the image region on the front surface and the toner amount Mf in the bonding region on the front surface were both 0.2 mg/cm2 and were smaller than the toner amount 0.3 mg/cm2 with which a high-quality image balanced in the density and the consumption amount can be obtained, and thus lack of density occurred. In Comparative Example 1, the toner amount Mgf in the image region on the front surface was small, and therefore the consumption amount was small. In addition, in Comparative Example 1, since the toner amount Mgr in the image region on the back surface was 0.4 mg/cm2 equal to the toner amount Mr in the bonding region on the back surface and was larger than the appropriate toner amount 0.3 mg/cm2, the density was sufficient but the consumption amount was large.
In contrast, in the first embodiment, the exposure light amount is changed in accordance with the position in the main scanning direction, that is, changed to Rf in the bonding region on the front surface, Rr in the bonding region on the back surface, and Rt in the image regions on the front surface and the back surface. As a result of this, the toner amount Mf in the bonding region on the front surface is set to 0.2 mg/cm2, the toner amount Mr in the bonding region on the back surface is set to 0.4 mg/cm2, the toner amounts Mgf and Mgr in the image regions on the front surface and the back surface are set to 0.3 mg/cm2. As a result of this, a high-quality image further balanced in the density and the consumption amount can be obtained while obtaining a good result in the bonding force and the reduction of the toner attachment to the pressurizing plate 62.
To be noted, although the exposure light amount in the bonding region on the front surface is controlled to the light amount Rf by changing the PWM of the image signal 109 in the present embodiment, the configuration is not limited to this. The exposure light amount in the bonding region may be set to be smaller than that in the image region by setting a voltage larger than the voltage Vc as the correction current amount signal 113 output to the bonding region. Alternatively, by combining on and off of the semiconductor laser 100 on the per scanning unit basis (per laser spot basis), the exposure light amount in the bonding region can be virtually reduced.
In addition, in the present embodiment, a configuration example (
In the present embodiment, an image forming apparatus that can change the size of the sheet P to be used for forming the booklet will be described. It is assumed that the bonding toner image of the present embodiment is formed at a long-side edge portion as illustrated in
In the description below, it is assumed that elements denoted by the same reference signs as in the first and second embodiments have substantially the same configuration and function as those described in the first and second embodiments unless otherwise described, and parts different from the first and second embodiments will be mainly described.
The overall configuration of the image forming apparatus 200S according to the third embodiment is the same as that described in the second embodiment (
Exposure control of the present embodiment will be described with reference to
The time after the elapse of the time tg4 from the falling edge is a time at which a position on the photosensitive drum Dn corresponding to a position at 2 mm from an end portion in the Y direction of the sheet P of the A4 size is scanned by the scanning light L3. In addition, the time after the elapse of the time tr4 from the falling edge is a time at which a position on the photosensitive drum Dn corresponding to a position at 5 mm from an end portion in the Y direction of the sheet P of the A4 size is scanned by the scanning light L3. By setting the times tg4 and tr4 in this manner, a light amount profile corresponding to the sheet P of the A4 size can be set. That is, a region on the photosensitive drum Dn corresponding to the bonding region on the sheet P of the A4 size can be exposed by the light amount Rr, and a region on the photosensitive drum Dn corresponding to the image region on the sheet P of the A4 size can be exposed by the light amount Rt.
The control of the exposure light amount when forming a bonding toner image on the back surface of the sheet P of the A4 size is substantially the same as that of the front surface except that the PWM control is preformed such that the density is a density Dh lower than the density of 100% in a region on the photosensitive drum Dn corresponding to the bonding region of the sheet P (see
The time after the elapse of the time tg5 from the falling edge is a time at which a position on the photosensitive drum Dn corresponding to a position at 2 mm from an end portion in the Y direction of the sheet P of the A5 size is scanned by the scanning light L3. In addition, the time after the elapse of the time tr5 from the falling edge is a time at which a position on the photosensitive drum Dn corresponding to a position at 5 mm from an end portion in the Y direction of the sheet P of the A5 size is scanned by the scanning light L3. By setting the times tg5 and tr5 in this manner, a light amount profile corresponding to the sheet P of the A5 size can be set. That is, a region on the photosensitive drum Dn corresponding to the bonding region on the sheet P of the A5 size can be exposed by the light amount Rr, and a region on the photosensitive drum Dn corresponding to the image region on the sheet P of the A5 size can be exposed by the light amount Rt.
The control of the exposure light amount when forming a bonding toner image on the back surface of the sheet P of the A5 size is substantially the same as that of the front surface except that the PWM control is preformed such that the density is a density Dh lower than the density of 100% in a region on the photosensitive drum Dn corresponding to the bonding region of the sheet P (see
As described above, in the present embodiment, the controller 107 and the correction current generation portion 105 serving as a light amount correcting portion selectively uses a plurality of light amount profiles in accordance with the size of the sheet in the main scanning direction. The plurality of light amount profiles are profiles different in the range irradiated with the scanning light L3 by the light amount Rr or Rf in the main scanning direction, and are determined in advance in accordance with the size of the sheet.
According to the present embodiment, the toner amount (toner deposition amount) per unit area in the bonding region on the sheet and the toner amount (toner deposition amount) per unit area in the image region can be changed by changing the light amount during exposure. That is, according to the present embodiment, the toner amount at the bonded portion can be changed as necessary. In addition, according to the present embodiment, by adjusting the change timing of the exposure light amount in accordance with the size of the sheet P, an effect similar to the first and second embodiments can be obtained in the booklet making apparatus 50 capable of forming a booklet by using sheets P of various sizes.
In the present embodiment, a configuration in which the exposure light amount can be changed between the bonding region and the image region similarly to the second embodiment even in a laser driving circuit configuration in which changing the laser driving current in accordance with the position in the main scanning direction is difficult as in the first embodiment.
In the description below, it is assumed that elements denoted by the same reference signs as in the first to third embodiments have substantially the same configuration and function as those described in the first to third embodiments unless otherwise described, and parts different from the first to third embodiments will be mainly described.
The overall configuration of the image forming apparatus 200S according to the fourth embodiment is the same as that described in the second embodiment (
The exposure control of the scanner unit 2 of the present embodiment will be described with reference to
The laser driving current 112 is repeatedly turned on and off in accordance with the image signal 109 corresponding to the density Dr in the bonding region and the density Dg in the image region. As a result of this, the region on the photosensitive drum Dn corresponding to the bonding region on the back surface of the sheet P is scanned by the scanning light L3 of a light amount Pr, and the region on the photosensitive drum Dn corresponding to the image region on the back surface of the sheet P is scanned by the scanning light L3 of a light amount Pg smaller than the light amount Pr of the bonding region.
The laser driving current 112 is repeatedly turned on and off in accordance with the image signal 109 corresponding to the density Dh in the bonding region and the density Dg in the image region. As a result of this, the region on the photosensitive drum Dn corresponding to the bonding region on the front surface of the sheet P is scanned by the scanning light L3 of a light amount Ps smaller than the light amount Pg of the image region, and the region on the photosensitive drum Dn corresponding to the image region on the front surface of the sheet Pis scanned by the scanning light L3 of the light amount Pg.
As described above, the controller 107 serving as a light amount correcting portion of the present embodiment corrects the light amount of the scanning light L3 emitted from the scanner unit 2 by the pulse width modulation of the image signal 109.
According to the present embodiment, the toner amount in the bonding region and the toner amount in the image region on the sheet P can be independently controlled in accordance with the position in the main scanning direction even in the configuration in which the laser driving current is not changed in accordance with the position in the main scanning direction. Therefore, an effect similar to the first embodiment can be obtained by setting the amount of the bonding toner Tn applied on the surface (first surface) of the sheet P that comes into contact with the pressurizing plate 62 during the formation of the booklet to be smaller than the amount of the bonding toner Tn applied on the surface (second surface) of the sheet P opposing the first surface.
According to the present embodiment, the toner amount (toner deposition amount) per unit area of the bonding region on the sheet and the toner amount (toner deposition amount) per unit area of the image region can be changed by changing the light amount during exposure. That is, according to the present embodiment, the toner amount at the bonded portion can be changed as necessary. In addition, by changing the control time of the image signal 109 and the correction current amount signal 113 in accordance with the size of the sheet P similarly to the third embodiment, an effect similar to the third embodiment can be obtained.
As described above, according to the present disclosure, an image forming apparatus that can change the toner amount at the bonded portion as necessary can be provided.
Embodiment(s) of the present invention can also be realized by a computer of a system or apparatus that reads out and executes computer executable instructions (e.g., one or more programs) recorded on a storage medium (which may also be referred to more fully as a ‘non-transitory computer-readable storage medium’) to perform the functions of one or more of the above-described embodiment(s) and/or that includes one or more circuits (e.g., application specific integrated circuit (ASIC)) for performing the functions of one or more of the above-described embodiment(s), and by a method performed by the computer of the system or apparatus by, for example, reading out and executing the computer executable instructions from the storage medium to perform the functions of one or more of the above-described embodiment(s) and/or controlling the one or more circuits to perform the functions of one or more of the above-described embodiment(s). The computer may comprise one or more processors (e.g., central processing unit (CPU), micro processing unit (MPU)) and may include a network of separate computers or separate processors to read out and execute the computer executable instructions. The computer executable instructions may be provided to the computer, for example, from a network or the storage medium. The storage medium may include, for example, one or more of a hard disk, a random-access memory (RAM), a read only memory (ROM), a storage of distributed computing systems, an optical disk (such as a compact disc (CD), digital versatile disc (DVD), or Blu-ray Disc (BD)™), a flash memory device, a memory card, and the like.
While the present invention has been described with reference to exemplary embodiments, it is to be understood that the invention is not limited to the disclosed exemplary embodiments. The scope of the following claims is to be accorded the broadest interpretation so as to encompass all such modifications and equivalent structures and functions.
This application claims the benefit of Japanese Patent Application No. 2023-086347, filed on May 25, 2023, which is hereby incorporated by reference herein in its entirety.
Number | Date | Country | Kind |
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2023-086347 | May 2023 | JP | national |