JP2019038680A - Conveying device and image forming apparatus - Google Patents

Abstract

To suppress abrasion of a conveying belt.SOLUTION: When a total opening area of a plurality of communication ports 52 communicating with a suction chamber D is α (unit: mm), and a total opening area of holes 31a of a conveying belt 31 positioned above a plurality of opening parts 51 provided to a plurality of recessed parts 50 communicating with the suction chamber D out of a plurality of holes 31a of the conveying belt is β (unit: mm), a plurality of the communication ports 52 communicating with the suction chamber D satisfies a relationship of α/β<0.01.SELECTED DRAWING: Figure 4

Description

  The present invention relates to a conveyance device that conveys a recording material and an image forming apparatus in which the conveyance device is used.

  Conventionally, as one method for conveying a recording material in an image forming apparatus, there is known a method for conveying a recording material while sucking it from the inside of a conveying belt (Patent Document 1). In this method, since the recording material is adsorbed and conveyed by the conveyance belt that is driven to rotate, it can be conveyed while ensuring the flatness of the recording material to be conveyed.

  Patent Document 1 discloses a configuration in which a long groove portion is provided on the upper surface of a platen positioned inside a conveyance belt that conveys a recording material, and a small hole portion is provided on the bottom surface of the long groove portion. . The small hole portion is connected to an opening portion penetrating the inside and outside of the platen. In the configuration of Patent Document 1, the suction fan sucks the inside of the platen, so that a negative pressure is generated in the small hole portion.

JP 2009-249060 A

  However, in the configuration of Patent Document 1, a negative pressure is generated in the small hole portion and the long groove portion when the suction fan sucks the inside of the platen regardless of whether or not the transport belt is transporting the recording material. . Therefore, in the configuration in which the inner peripheral surface of the transport belt is in contact with the upper surface of the platen, the transport belt rotates while the inner peripheral surface is always sucked by the upper surface of the platen. That is, the conveyor belt slides on the upper surface of the platen by rotation. For this reason, when the conveyor belt rotates for a long period of time, there is a concern that the conveyor belt may be worn by sliding friction with the upper surface of the platen. In particular, when the recording material is attracted with a larger negative pressure in order to keep the flatness and transportability of the recording material constant, the sliding friction may increase.

  Therefore, an object of the present invention is to suppress wear of the conveyor belt.

In order to achieve the above object, the first invention provides:
An endless belt having a plurality of holes, and a conveying belt for conveying a recording material;
A roller that is in contact with an inner peripheral surface of the conveyor belt and stretches the conveyor belt;
A suction section for sucking the recording material conveyed by the conveyance belt from the inside of the conveyance belt;
A conveying device comprising:
The suction part is
A suction chamber;
A fan for sucking air in the suction chamber;
A plurality of recesses having an opening that is open toward the inner peripheral surface side of the conveyor belt, and a communication port that is an opening having an opening area smaller than the opening and communicates with the suction chamber;
Have
The total opening area of the plurality of communication ports communicating with the suction chamber is α (unit: mm ² ), and the plurality of recesses communicating with the suction chamber among the plurality of holes of the transport belt has When the total opening area of the holes of the conveying belt positioned on the plurality of openings is β (unit: mm ² ), the plurality of communication ports communicating with the suction chamber are α / β < It satisfies the relationship of 0.01.

In addition, the second invention,
An endless belt having a plurality of holes, and a conveying belt for conveying a recording material;
A roller that is in contact with an inner peripheral surface of the conveyor belt and stretches the conveyor belt;
A suction section for sucking the recording material conveyed by the conveyance belt from the inside of the conveyance belt;
A conveying device comprising:
The suction part is
A suction chamber;
A fan for sucking air in the suction chamber;
A plurality of recesses forming an opening on the inner peripheral surface side of the conveyor belt, and an opening having an opening area smaller than the opening and communicating with the suction chamber;
Have
The total opening area of the plurality of communication ports connected to the suction chamber is α (unit: mm ² ), and the total opening area of the openings of the plurality of recesses connected to the suction chamber is γ (unit : Mm ² ), the plurality of communication ports connected to the suction chamber satisfy the relationship of α / γ <0.01.

In addition, the third invention,
An image forming unit that forms an image of the liquid developer on a recording material using a liquid developer including a toner and a liquid carrier that is cured by ultraviolet rays;
An ultraviolet irradiation unit that irradiates the liquid developer image formed on the recording material by the image forming unit with ultraviolet rays;
An endless belt having a plurality of holes, wherein the recording material carrying an image of the liquid developer formed by the image forming unit is conveyed so as to pass through a region irradiated with ultraviolet rays by the ultraviolet irradiation unit. A transport belt for transporting, and
A roller that is in contact with an inner peripheral surface of the conveyor belt and stretches the conveyor belt;
A suction section for sucking the recording material conveyed by the conveyance belt from the inside of the conveyance belt;
An image forming apparatus having
The suction part is
A suction chamber;
A fan for sucking air in the suction chamber;
A plurality of recesses that form an opening that opens toward the inner peripheral surface side of the conveyor belt, and an opening that has an opening area smaller than the opening and communicates with the suction chamber;
Have
The total opening area of the plurality of communication ports communicating with the suction chamber is α (unit: mm ² ), and the plurality of recesses communicating with the suction chamber among the plurality of holes of the transport belt has When the total opening area of the holes of the conveying belt positioned on the plurality of openings is β (unit: mm ² ), the plurality of communication ports communicating with the suction chamber are α / β < It satisfies the relationship of 0.01.

  According to the present invention, since the total opening area of the plurality of communication ports communicating with the suction chamber is sufficiently small, the force with which the conveyance belt is sucked when there is no recording material on the conveyance belt can be suppressed. The wear of the conveyor belt can be suppressed.

It is a perspective view explaining the structure of a conveying apparatus. It is a figure explaining the structure of a plane plate. It is a schematic diagram explaining the structure of the suction hole provided in a conveyance belt. It is a schematic diagram explaining a conveyance and suction suction operation. It is a figure explaining the correlation of a suction force and opening ratio. 1 is a schematic cross-sectional view of an image forming apparatus.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following, a recording material conveying apparatus will be described by taking as an example a case where the recording material conveying apparatus is applied to an electrophotographic image forming apparatus using a liquid developer that is cured by ultraviolet rays. More specifically, an example will be described in which an image formed by a liquid developer formed on a recording material by an electrophotographic method is applied to a fixing unit that is fixed by ultraviolet rays. However, the components described in this embodiment are merely examples, and the present invention is not limited to only those described in the embodiment. For example, the recording material conveying apparatus described below can be applied to an electrophotographic or electrostatic recording type image forming apparatus (including a copying machine and a laser beam printer) using a dry toner, or an ink jet type image forming apparatus. It is.

[Example 1]
(Image forming device)
FIG. 6 is a schematic diagram illustrating an example of the configuration of the image forming apparatus. The image forming apparatus 100 includes an image forming unit 10 that forms an image with an unfixed liquid developer by electrophotography using a liquid developer containing toner and an ultraviolet curable liquid carrier on a recording material 16. Further, the image forming apparatus 100 includes a fixing unit 11 that fixes an unfixed image 15 formed on the recording material 16 onto the recording material 16 by irradiation with ultraviolet rays.

  Here, the recording material 16 is a sheet-like medium on which an image formed by the liquid developer can be formed by the image forming apparatus 100, and includes, for example, recording materials such as plain paper, coated paper, postcards, and envelopes. For example, the recording material 16 may be an OHP sheet or a film. For convenience, the handling of the recording material 16 will be described using terms related to paper such as paper passing, paper feeding, paper discharging, paper passing portion, and non-paper passing portion, but the recording material is not limited to paper.

  The cassette 25 is a storage unit that stores the recording material 16 used for image formation. The recording material 16 accommodated in the cassette 25 is fed to the image forming unit 10 by the feeding mechanism 2. The feed mechanism 2 is, for example, a paper feed roller, and feeds the recording material 16 in the cassette 25 to the transport path 26. Note that the storage section may have a plurality of cassettes, or may have a tray shape (for example, a manual feed tray).

  The recording material 16 fed from the cassette 25 by the feeding mechanism 2 is supplied to the image forming unit 10 through the transport path 26. More specifically, the toner is supplied to a contact portion between the image holding member 1 and the transfer unit 4. After the image on the outer peripheral surface of the image holding member 1 is transferred by the transfer unit 4 at the contact portion between the image holding member 1 and the transfer unit 4, the recording material 16 passes through the conveyance path to the fixing unit 11. Be transported.

  The image forming unit 10 forms an image 15 of the liquid developer on the recording material 16 using the liquid developer by electrophotography. The liquid developer includes a liquid carrier containing an ultraviolet curing agent (curing agent) that is cured by ultraviolet rays, and a toner.

  The image forming unit 10 may be a direct transfer method or an intermediate transfer method having an intermediate transfer member.

  In the case of the direct transfer method, the image holding member 1 is a photosensitive drum as a photosensitive member. The image holding member 1 in this embodiment has an organic photoreceptor surface layer on the surface of an aluminum cylinder (photosensitive drum) having a thickness of 3 mm and an outer diameter of 84 mm, and has a long side width (a direction substantially perpendicular to the recording material conveyance direction). Is 370 mm. The image holding member 1 is rotationally driven in the direction of arrow R2 in FIG. 6 about a central support shaft by a drive motor as a driving means (not shown) of the image holding member 1. An electrophotographic image forming means (not shown) develops a latent image using a charging unit that charges the image holding member 1 to a uniform surface potential, an exposure unit that forms a latent image by exposure, and a liquid developer. A developing unit is provided, and an image is formed on the outer peripheral surface of the image holding member 1. The liquid developer image 15 formed on the image holding member 1 is transferred onto the recording material 16 by a transfer roller as the transfer means 4. Here, an ultraviolet curable liquid carrier is also transferred onto the recording material 16 as an unfixed image 15 together with the toner.

  In this example, the image forming unit 10 has a configuration of an electrophotographic direct transfer system, but the image forming method on the recording material 16 is not limited to this. For example, an intermediate transfer type configuration in which the image holding member 1 is an intermediate transfer belt may be used. Specifically, the primary transfer roller primarily transfers the image 15 of the liquid developer formed on the photosensitive drum by the image forming means (not shown) on the photosensitive drum, and the transfer means 4 The image 15 on the intermediate transfer member is transferred to the recording material 16 as a secondary transfer roller.

  The recording material 16 on which the image 15 of the liquid developer is formed in the image forming unit 10 is conveyed to the fixing unit 11 through the conveyance path 27. The fixing unit 11 includes an infrared irradiation device (infrared irradiation unit) 13, an ultraviolet irradiation device (ultraviolet irradiation unit) 12, and a conveying device 30. The infrared irradiation device 13 heats the liquid developer by irradiating the image 15 with the liquid developer on the recording material 16 with infrared rays. The ultraviolet irradiation device 12 cures the ultraviolet curing agent in the liquid developer by irradiating the image 15 with the liquid developer on the recording material 16 with ultraviolet rays. That is, the ultraviolet irradiation device 12 fixes the liquid developer image 15 on the recording material 16 by curing the liquid carrier on the recording material 16 with ultraviolet light.

  The recording material 16 fixed by the fixing unit 11 passes through a discharge conveyance path 28 and is discharged outside the apparatus.

(Overall configuration of transfer device)
The fixing unit 11 includes a transport device 30 that transports a recording material 16 that carries an image 15 of an unfixed liquid developer.

  The conveyance device 30 conveys the recording material 16 so that the recording material 16 on which the image 15 of the unfixed liquid developer is formed by the image forming unit 10 passes through the infrared irradiation position and the ultraviolet irradiation position. Here, the infrared irradiation position refers to a position that is the center of a region having an illuminance of 90% or more of the peak illuminance of the infrared irradiation device 13 when viewed in the position distribution in the conveyance direction of the recording material 16. Further, the ultraviolet irradiation position refers to a position where the maximum illuminance (peak illuminance) by the ultraviolet irradiation apparatus 12 is obtained when viewed in the position distribution in the conveyance direction of the recording material 16.

  The transport device 30 is a suction transport device that transports the recording material 16 while sucking it.

  Specifically, the conveying device 30 includes an endless conveying belt (endless belt) 31 provided with a number of suction holes 31a (FIG. 3), and a driving roller 35 and a driven roller 36 that stretch the conveying belt 31. , 37, 38. In FIG. 1, some of the holes provided in the conveyor belt 31 are omitted for simplification of the drawing, but the holes 31 a are distributed in the entire circumferential direction on the conveyor belt 31. Yes. The conveyor belt 31 in this embodiment has a width of 350 mm and a circumferential length of 900 mm.

  Further, the transport device 30 includes a drive motor (not shown) that rotates the transport belt 31 via the drive roller 35. The conveyor belt 31 is rotated in the direction of the arrow R2 shown in FIG. 6 by driving of the drive motor.

  The transport device 30 has a suction unit for sucking the recording material 16 transported by the transport belt 31 to the peripheral surface of the transport belt 31 through a number of suction holes 31 a formed in the transport belt 31. The suction unit has a suction fan 34. The suction unit sucks the recording material 16 on the transport belt 31 from the inside of the transport belt 31. That is, the suction fan 34 sucks the recording material 16 onto the upper surface of the transport belt 31 by sucking air in a direction from the upper surface side of the transport belt 31 toward the inner side of the transport belt 31. The transport device 30 transports the recording material 16 while adsorbing the recording material 16 onto the transport belt 31. Thereby, the recording material 16 can be transported without contacting the image 15 of the unfixed liquid developer on the recording material 16.

  The configuration of the conveyance device 30 in the fixing unit 11 will be described in detail with reference to FIG. FIG. 1 is a cross-sectional perspective view of the transfer device 30.

  In the following description, the vertical direction in the transport device 30 refers to a direction orthogonal to the transport surface of the recording material 16. That is, the upper surface of the member of the transport device 30 refers to the surface on the side carrying the recording material 16 in the vertical direction, and the lower surface of the member of the transport device 30 refers to the surface opposite to the upper surface in the vertical direction. In the following description, the width direction is a direction orthogonal to the conveyance direction of the recording material 16 on the conveyance surface of the recording material.

  The conveying device 30 holds a driving roller 35 that drives the conveying belt 31, driven rollers 36, 37, and 38 that are driven to rotate with respect to the conveying belt 31, a driving motor (not shown) that is a driving source of the driving roller 35, and the like. Has a frame. Further, the transport device 30 is provided with a flat plate 32 having a suction groove 50, a suction pedestal 33, and a suction fan 34 connected to the suction pedestal 33. The flat plate 32 and the suction pedestal 33 are located inside the conveyor belt 31. The suction fan 34 may be positioned outside the transport belt 31 as shown in FIG.

  The flat plate 32 is disposed between the driving roller 35 and the driven roller 36, and the conveyor belt 31 rotates so as to rub against the upper surface (contact surface) of the flat plate 32. A suction pedestal 33 is disposed below the flat plate 32. The flat plate 32 is a top plate of the suction pedestal 33. Air is sucked into the space D (suction chamber) formed by the lower surface of the flat plate 32 and the suction base 33 by the suction fan 34. Due to the air suction of the suction fan 34, the space D becomes a negative pressure regardless of whether or not there is an object to be transported on the transport belt 31. A boundary portion between the flat plate 32 and the suction base 33 is sealed with an elastic member that prevents air leakage.

  In this embodiment, the suction pedestal 33 is divided into two rooms. That is, the flat plate 32 and the suction pedestal 33 form two spaces D. These spaces D are independent from each other and do not communicate with each other. One suction fan 34 is provided for each space D. However, the number of spaces D formed by the flat plate 32 and the suction pedestal 33 is not limited to two. For example, the plane plate 32 and the suction pedestal 33 may be configured to form one space D, and one suction fan 34 may be configured to suck the space D, or one space D may be sucked by two or more suction fans. It is good also as composition to do.

  The conveyance belt 31 is provided with a plurality of suction holes 31a through which suction air from the suction fan 34 flows, and the recording material 16 conveyed by the conveyance device 30 closes the suction holes 31a so that the recording material 16 is conveyed. Adsorbed to the belt 31.

  Next, the flat plate 32 will be described with reference to FIG. FIG. 2A is a cross-sectional perspective view of the flat plate 32. FIG. 2B is an enlarged view of the round portion illustrated in FIG.

  As shown in FIG. 2, a large number of suction grooves (concave portions) 50 are provided on the surface of the flat plate 32 that rubs against the transport belt 31 in the transport direction of the recording material 16.

  The space D communicates with the outside of the suction pedestal 33 and the flat plate 32 through a communication hole 52 and an opening 51 provided in the flat plate 32. The suction groove 50 forms a space between the communication hole 52 and the opening 51.

  In FIG. 2, reference numeral 51 denotes an edge (ridge line, edge) portion of the suction groove 50 in the upper part of the flat plate 32. The portion indicated by reference numeral 51 forms an opening of the suction groove 50 toward the inner peripheral surface side of the conveyor belt 31 and is therefore referred to as an opening 51. The opening 51 forms a rectangular opening that is long in the width direction.

  A communication hole (communication port) 52 penetrating the flat plate 32 is provided on the bottom surface of each suction groove 50. In the present embodiment, one suction hole 52 is provided in each suction groove 50. A space D (suction chamber) formed by the lower surface of the flat plate 32 and the suction pedestal 33 and the suction groove 50 of the flat plate 32 are spatially connected by a communication hole 52.

  Although a plurality of communication holes 52 may be provided for one suction groove 50, the communication holes 52 are formed in each suction groove 50 from the viewpoint of the condition of the opening area ratio described later and clogging of the communication holes 52. On the other hand, it is desirable that there is one each.

The communication hole 52 connected to the space D (suction chamber) formed by the lower surface of the flat plate 32 and the suction base 33 is sufficiently small with respect to one space D. As a result, the suction fan 34 regardless of whether or not the recording material 16 exists on the transport belt 31 in the space D (suction chamber) formed by the lower surface of the flat plate 32 and the suction base 33. A predetermined negative pressure can be generated by operating the. Here, the negative pressure is a pressure lower than the reference pressure. When the negative pressure is P, the reference pressure is P ₀ , and the absolute pressure is P ₁ , the magnitude of the negative pressure P is the absolute value of the differential pressure. That is, the negative pressure | P | = | P ₁ −P ₀ |.

  In order to stably convey the recording material 16, the conveying device 30 is required to have a sufficient suction force.

  If the suction force is insufficient, the transportability of the recording material 16 is not stable. Specifically, a jam occurs in the fixing unit 11 due to the fluttering of the recording material 16, or the unfixed image 15 of the curled recording material 16 contacts a member in the fixing unit 11, so that the image is formed. There is a risk of disturbance.

  In view of these, it is preferable that the conveyance device 30 in the fixing unit 11 has a suction force of 200 Pa or more.

  In the present embodiment, a negative pressure of 200 Pa or more (that is, | P | ≧ 200 Pa) is generated in the space D by operating the suction fan 34 in a state where there is no object to be transported on the transport belt 31. Here, the reference pressure is the pressure in the suction groove 50. That is, the absolute pressure in the space D is 200 Pa lower than the pressure in the suction groove 50 that is the reference pressure.

  In more detail, the reference pressure is a position where the communication hole 52 is not affected by the slight air flow as much as possible, that is, a pressure at a point farthest from the communication hole 52 in the suction groove 50. In this embodiment, as will be described later, the suction portion includes suction grooves 50 having different sizes. In this case, the pressure in the suction groove 50 having the largest opening 51 among the suction grooves 50 communicating with the space D is set as the reference pressure.

  As will be described later, in the suction portion of this embodiment, the total opening area of the opening 51 is sufficiently larger than the total opening area of the communication hole 52. Thereby, the pressure in the suction groove 50 becomes substantially equal to the atmospheric pressure in the space on the conveyance belt 31. That is, if the internal pressure in the image forming apparatus 100 is equal to the atmospheric pressure, the reference pressure is almost atmospheric pressure.

  On the other hand, when the conveyance belt 31 conveys the recording material 16, the recording material 16 on the conveyance belt 31 closes the suction hole 31 a of the conveyance belt 31. As a result, the suction groove 50 located below the region where the recording material 16 is carried becomes a closed space, and the suction groove 50 also has a predetermined negative pressure (here, the same pressure as the space D, that is, the negative pressure | P | = 200 Pa) works. As a result, a suction force can be applied to the recording material 16 on the transport belt 31.

  The suction groove 50 is provided in a plurality of parts in the width direction. In the present embodiment, a plurality of suction grooves 50 are provided so as to be symmetric with respect to the center line in the width direction of the flat plate 32. The suction groove 50 provided in the center in the width direction has a long groove length in the width direction, and a plurality of suction grooves 50 having a short width in the width direction are provided outside (both ends) in the width direction (FIG. 2). 3) are provided continuously. In this embodiment, the recording material 16 is conveyed (center reference paper passing) so that the center of the flat plate 32 in the width direction substantially coincides with the center of the width direction of the recording material 16 being conveyed.

  In order to generate a predetermined negative pressure (in this example, negative pressure | P | = 200 Pa) in the suction groove 50, the suction hole 31a of the transport belt 31 is blocked by the recording material 16 being transported. It is necessary that the groove 50 be a closed space. Therefore, the suction grooves 50 are divided into a plurality of portions in the width direction so as to correspond to various recording materials 16 having different sizes in the width direction.

  Here, in the width direction, the suction groove 50 (suction groove 50x in FIG. 2) having the largest groove length (opening width) in the width direction is provided in the minimum sheet passing area. Here, the minimum sheet passing area refers to an area through which all the recording materials that can be transported by the transport device 30 can pass when transported by the transport belt 31. As a result, even when a recording material having a minimum size in the width direction is conveyed, a suction force can be generated for the recording material having the minimum width, and the number of suction grooves 50 can be reduced. Since at least one communication hole 52 is required for one suction groove 50, a sufficiently small total opening area α of the communication holes 52 can be realized by reducing the number of suction grooves 50.

  Further, the width in the width direction of the suction groove 50 located on the outer side (both ends) is larger than the length in the width direction of the suction groove 50 at the center so that the end in the width direction of the recording material 16 can be more reliably adsorbed. Designed to be short. More specifically, the suction groove 50 (suction groove 50y in FIG. 2) corresponding to the area outside the minimum sheet passing area, that is, the area that becomes the non-sheet passing portion when the recording material of the minimum width size is conveyed is more than the suction groove 50x. Also shorten the groove length in the width direction. A plurality of suction grooves 50 having a groove length in the width direction shorter than the central portion are provided in a region that becomes a non-sheet passing portion when the recording material having the smallest size in the width direction is conveyed. Make it correspond.

  In this embodiment, the configuration in which eight suction grooves 50 are arranged in the width direction has been described as an example. However, the number of suction grooves 50 provided in the width direction is not limited thereto.

  The suction groove 50 is preferably provided with a length corresponding to at least the maximum size in the width direction of the recording material 16 capable of passing paper in the image forming apparatus 100 in the width direction.

  The recording material that can be transported by the transport device 30 refers to a recording material that can be passed by the image forming apparatus 100. The image forming apparatus 100 includes an input unit 200 to which the size of the recording material (including the size in the width direction) used by the operator is input. For example, the input unit 200 is an operation unit as a user interface. In the image forming apparatus 100, the recording material having the smallest size in the width direction is the smallest size in the width direction that can be input to the input unit 200 (or can accept input). In addition, the maximum size in the width direction is the maximum size in the width direction that can be input to the input unit 200 (or can accept input).

  Here, the flat plate 32, the suction base 33, the suction fan 34, the suction groove 50, and the communication hole 52 function as a suction portion.

  In the present embodiment, the flat plate 32 is made of metal (for example, SUS).

(Material of conveyor belt)
The conveyor belt 31 of the present embodiment is EPDM (ethylene / propylene / diene rubber) containing carbon black as a main component, and includes carbon black, a vulcanizing agent, a deterioration preventing agent, and the like as subcomponents. The purpose of containing carbon black is to efficiently absorb the irradiation heat of ultraviolet rays, and it is heated more efficiently than a conveyor belt that does not contain carbon black. The main component of the transport belt 31 may be nitrile rubber (NBR), chloroprene rubber (CR), urethane rubber, fluorine rubber, or silicon rubber. It is good also as a structure which contains the solid material (carbon material) comprised from carbon atoms, such as. Furthermore, the volume resistivity of the conveyor belt 31 is preferably less than 1010 (Ω · cm) from the viewpoint of making it difficult to charge the conveyor belt and preventing poor separation of the recording material 16. When the conveyor belt 31 is a rubber belt, it is preferable that the driving and driven tension rollers have a crown shape in which the shaft diameter at the center in the width direction is larger than the shaft diameter at both ends in the width direction. Since the automatic alignment is performed using the stretchability of the rubber belt, the conveyance belt 31 is held at the center in the width direction.

  In addition, the material of the conveyance belt 31 shown in the present embodiment is an example, and other materials may be used.

(Conveyor belt hole)
In FIG. 3, the schematic diagram of the shape of the conveyance belt 31 in a present Example is shown. The belt width W, which is the length of the conveyance belt 31 in the width direction, is equal to or larger than the maximum width direction size of the recording material 16 that can pass the sheet in the image forming apparatus 100. That is, it is equal to or larger than the maximum width of the size of the recording material 16 conveyed by the conveying device 30. This is because the entire recording material 16 to be conveyed can be uniformly sucked and adsorbed to the conveyance belt 31 in the width direction.

  The transport belt 31 has B = φ4 suction holes 31a that are inclined at G = 45 ° with respect to the transport direction (reference line in FIG. 3) and are evenly opened to the full width of the belt at intervals of E = 11 mm and F = 11 mm. It has been.

(Suction transfer operation of transfer device)
The manner in which the recording material 16 is sucked and conveyed by the conveying belt 31 will be described in detail with reference to FIG. FIG. 4 is a schematic cross section of the transfer device 30. The overall configuration of the transport device 30 is as described above with reference to FIGS.

  In FIG. 4, for convenience of explanation, the conveyance device 30 is schematically simplified. Therefore, although the shape may differ between FIGS. 1-3 and FIG. 4, regarding the thing with the same code | symbol, it is the same components as FIGS. For example, although the arrangement of the suction fan 34 differs between FIG. 1 and FIG. 4, FIG. 4 is schematically shown, and the actual arrangement in the present embodiment is as shown in FIG. Further, for example, the width and distribution of the suction holes 31a of the conveyance belt 31 in FIG. 4 are different from those in FIGS. 1 and 3, but FIG. 4 is simplified. 4A to 4D, the reference numerals are omitted, but the same configuration in FIG. 4 is the same member.

  FIG. 4 shows a state in which the recording material 16 gradually moves onto the conveyance belt 31 from the state before the conveyance belt 31 carries the recording material 16 (FIG. 4A) (FIGS. 4B to 4B). d)). As the recording material 16 moves from (a) to (d), the area where the recording material 16 is attracted to the conveyance belt 31 increases.

  4A, A is the diameter of the communication hole 52 of the flat plate 32, B is the diameter of the suction hole 31a of the conveyance belt 31, and C is the conveyance of the opening 51 of the suction groove 50 provided in the flat plate 32. The width of the direction. The arrow R1 indicates the conveyance direction of the recording material 16, and the arrow R2 is the rotation direction of the conveyance belt 31. A space D formed by the lower surface of the flat plate 32 and the suction pedestal 33 is connected to the suction groove 50 by the communication hole 52.

  In the suction portion, the space D is connected to the suction groove 50 through the communication hole 52, but the space D is maintained at a predetermined negative pressure (in this embodiment, negative pressure 200 Pa) by suction by the suction fan 34.

  On the other hand, the size of the communication hole 52 is sufficiently smaller than the size of the suction hole 31a of the transport belt 31 (or the size of the opening 51 of the suction groove 50). Although the detailed relationship of the size will be described later, the recording material 16 on the transport belt 31 covers the suction hole 31a of the transport belt 31 and the recording is sequentially performed each time the suction groove 50 is closed. The material 16 can be configured to generate a substantial suction force.

  In a state where there is no object to be transported on the transport belt 31, a predetermined negative pressure by the suction fan 34 does not act on the suction groove 50. The suction groove 50 is closed by the recording material 16 on the conveyance belt 31, so that a predetermined negative pressure by the suction fan 34 acts on the suction groove 50.

  That is, if the pressure in the suction groove 50 when there is no recording material 16 on the transport belt 31 is Px (unit: Pa), the Py in the suction groove 50 that is closed by the recording material 16 on the transport belt 31 is The pressure becomes 200 Pa or more smaller than Px.

  Hereinafter, in the description of FIG. 4, a case where the periphery of the transfer device 30 is atmospheric pressure will be described as an example.

  In FIG. 4A, the recording material 16 has not yet reached the transport device 30. At this time, the negative pressure by the suction fan 34 is not substantially applied to all the suction grooves 50 of the flat plate 32, and all the suction grooves 50 of the flat plate 32 are at atmospheric pressure. This is because the suction hole 31a of the transport belt 31 located on the opening 51 is not closed and the suction groove 50 is open.

  In FIG. 4B, the suction groove 50 a is covered with the recording material 16 on the conveyance belt 31. Thus, the suction groove 50 becomes a closed space, and the air in the suction groove 50a is sucked from the communication hole 52 and has the same pressure as the space D of the suction base 33 (that is, the suction force substantially acts). Then, the recording material 16 is sucked and attracted to the transport belt 31. The suction suction force is generated only in the suction groove 50a, and the suction grooves 50b to 50d are still at atmospheric pressure.

  In FIG. 4C, the recording material 16 is further conveyed, and the suction groove 50b is also covered with the recording material 16 following the suction groove 50a. In the suction groove 50 b, a suction suction force is generated similarly to the suction groove 50 a, and the recording material 16 is sucked and sucked to the transport belt 31. The suction grooves 50c to 50d are still at atmospheric pressure.

  In FIG. 4D, all the suction grooves 50 are covered with the recording material 16. At this time, suction force is generated in all of the suction grooves 50a to 50d, and the recording material 16 is adsorbed on the entire surface.

  Thus, when the recording material 16 covers the suction groove 50, a suction suction force is generated in the suction groove 50. That is, as the recording material 16 is transported in the transport direction by the transport belt 31, a substantial suction force by the suction fan 34 sequentially acts on the suction groove 50 in which the closed space is formed. Therefore, as the recording material 16 is conveyed by the conveying device 30, the recording material 16 is sequentially adsorbed by the conveying belt 31 so that the adsorption area of the recording material 16 is gradually enlarged for each opening width in the conveying direction of the suction groove 50. It goes.

  Here, as shown in FIG. 4, the conveying device 30 of the present embodiment is configured to sequentially generate a suction force every time the suction groove 50 is covered with the recording material 16. This is to suppress the sliding friction between them and to suppress the wear of the conveyor belt 31.

  As described above, in order to stably transport the recording material 16 by the transport device 30, the suction force with respect to the recording material 16 on the transport belt 31 is required to be 200 Pa or more.

  When a suction force of 200 Pa or more is applied to the recording material 16 by the suction portion, an equivalent suction force is also applied to the transport belt 31. Therefore, even when the recording material 16 is not present on the conveyance belt 31, if the suction force of 200 Pa or more is constantly applied to the conveyance belt 31, the inner peripheral surface of the conveyance belt 31 always has an upper surface of the flat plate 32 and 200 Pa or more. Continue to be rubbed while receiving suction force. The case where the recording material 16 does not exist on the conveying belt 31 during the suction operation of the suction fan 34 is, for example, between sheets in continuous paper passing. Further, for example, in a state in which the image forming apparatus 100 can start image formation, the image forming apparatus 100 is in a standby state in which the conveyance belt 31 is rotated while the suction fan 34 is operated and an image formation command is waited.

  In view of this, the conveying device 30 of this embodiment suppresses the wear of the conveying belt 31 by adopting a configuration in which a substantial suction force does not act on the suction groove 50 when the recording material 16 is not on the conveying belt 31. To do.

(Detailed configuration of suction device 1)
A configuration of the conveying device 30 that does not cause a substantial suction force to act on the suction groove 50 when there is no recording material 16 on the conveying belt 31 will be described.

Specifically, the total opening area (α) of the plurality of communication holes 52 vacant so as to be connected to one space D is set on the openings 51 of the plurality of suction grooves 50 connected to the space D. It is made sufficiently small with respect to the total opening area (β) of the suction holes 31 of the conveying belt 31 positioned. That is, α <β. More specifically, the total opening area α of the plurality of communication holes 52 vacant so as to be connected to one space D is located on the openings 51 of the plurality of suction grooves 50 connected to the space D. The total opening area β of the suction holes 31a of the transport belt 31 is less than 1.0%. That is, α / β <0.01. The unit of α and β is mm ² .

For example, 100 communication holes 52 connected to one space D are vacant, and one of these communication holes 52 is provided in one suction groove 50 (that is, 100 suction grooves 50 are provided). Yes). The diameter of one communicating hole 52 is A, and the opening area is X _A (mm ² ). The opening areas of the 100 communication holes 52 are all the same. In this case, a total opening area α = 100 × _{X A.} Further, the total opening area of the suction holes 31a of the transport belt 31 located on the openings 51 of the 100 suction grooves 50 is β.

  If the size of the opening 51 of the suction groove 50 and the size of the suction hole 31a of the conveying belt 31 on the opening 51 are approximately the same as those of the communication hole 52, the following occurs. That is, if air suction operation is performed by the suction fan 34 in order to make the space D have a negative pressure of | P | = 200 Pa or more, the suction groove 50 also has a negative pressure of | P | = 200 Pa or more. This is because in order to apply a sufficient suction force to the recording material 16 on the transport belt 31 through the communication hole 52 that is as large as the suction groove 50 or the suction hole 31a, regardless of the presence or absence of the recording material 16, This is because a negative pressure of 200 Pa or more must be applied to the suction groove 50. With such a configuration, the sliding friction of the conveyor belt 31 cannot be suppressed. Therefore, it is preferable that the opening 51 and the suction hole 31 a of the transport belt 31 on the opening 51 are sufficiently larger than the communication hole 52.

  On the other hand, when the recording material 16 is transported, the suction groove 50 is covered with the recording material 16 so that a suction force of 200 Pa is instantaneously generated in the suction groove 50, so that the recording material 16 is not on the transport belt 31. Therefore, it is required that the space D has a negative pressure | P | = 200 Pa or more. When the opening area of the communication hole 52 is large, in order to generate a negative pressure of 200 Pa or more in the space D, the air flow rate (suction amount) by the suction fan must be increased. In a configuration requiring a large air flow rate, the suction fan 34 is increased in size and power consumption by the suction fan 34 is increased. Therefore, the communication hole 52 is preferably sufficiently small with respect to the space D.

In this embodiment, when the total opening area of the openings 51 of the suction groove 50 communicating with one space D is γ (unit: mm ² ), β <γ. Therefore, in this embodiment, the pressure in the suction groove 50 according to the presence or absence of the recording material 16 on the transport belt 31 is the transport belt positioned on the openings 51 of the plurality of suction grooves 50 connected to the space D. The total opening area (β) of the 31 suction holes 31 is dominantly determined.

(Detailed configuration 2 of suction device)
Next, a more optimal configuration of the suction device will be described.

  First, the size of the communication hole 52 will be described. If the opening area of each communication hole 52 is too small, the hole may be clogged by foreign matters such as dust. Therefore, the minimum opening width of the communication hole 52 is desirably 1.0 mm or more. In this embodiment, φ1.1 mm is taken as an example.

  Here, the opening width of the communication hole 52 refers to a diameter having the smallest opening diameter in the communication hole 52. For example, in the case of an ellipse, the length of the minor axis is the opening width (minimum opening width).

  Next, the width C in the transport direction of the suction groove 50 will be described. For the following reason, the width C in the transport direction of the suction groove 50 is desirably 3.0 mm or more and 30.0 mm or less. In this embodiment, as an example, the C width is 5.0 mm.

  As described above, the substantial suction and suction force is generated when the suction groove 50 is closed by the recording material 16 on the conveyance belt 31. The suction groove 50 has a width C in the conveyance direction of 30.0 mm so that the recording material 16 can be reliably adsorbed when the amount of the engagement (length in the conveyance direction) is small after the leading edge of the recording material 16 starts to be on the conveyance belt 31. The following.

  From the viewpoint of increasing the reliability related to the conveyance of the recording material 16, the smaller the width C, the better. In particular, in order to reliably suck and attract the curled recording material or cardboard onto the transport belt, it is preferable to reduce the width C in the transport direction of the suction groove 50 and quickly complete the sealed state of the suction groove 50. Further, the fact that the suction groove width C is small also has an effect that the curl correction capability is improved and the flatness of the suction paper is improved.

  On the other hand, in order to generate the suction force in the suction groove 50, at least one communication hole 52 is required for one suction groove 50. If the width C of the suction groove 50 is too narrow, the total number of communication holes 52 provided in the flat plate 32 increases. In order to maintain the space D at a predetermined negative pressure with a smaller air flow rate, it is necessary to relatively reduce the opening area of each communication hole 52.

  Considering that the minimum opening width of the communication hole 52 is preferably 1.0 mm or more, the width C in the transport direction of the suction groove 50 is desirably 3.0 mm or more.

  As for each shape, it is desirable that the suction groove 50 has a rectangular shape that is long in the width direction from the viewpoint of increasing the suction area, and the suction hole 31a and the communication hole 52 of the transport belt are round for ease of processing. A hole is desirable.

(Air flow rate of suction fan)
FIG. 5 shows the suction force on the vertical axis and the opening area ratio on the horizontal axis, and shows the relationship between the air flow rate by the suction fan 34 and the suction force.

The horizontal axis of FIG. 5 is connected to this space D with respect to the total opening area (β) of the suction holes 31 of the conveying belt 31 located on the openings 51 of the plurality of suction grooves 50 connected to one space D. The ratio of the total opening area (α) of the plurality of communication holes 52 is expressed as a percentage. That is, α / β is expressed as a percentage. The unit of α and β is mm ² .

  The vertical axis in FIG. 5 is the absolute value of the negative pressure that acts in the space D when the recording material 16 is not on the transport belt 31. When the suction groove 50 is closed by the recording material 16 on the conveyance belt 31, a suction suction force corresponding to the value on the vertical axis is applied to the recording material 16.

  The curve in FIG. 5 is the air flow rate by the suction fan 34. That is, the graph of FIG. 5 shows the relationship between the suction air flow rate and the suction force by the suction fan 34. Although the legend of the graph of FIG. 5 is shown by the flow velocity, it is because the air flow rate is compared with the air flow rate per unit area.

  A large opening area ratio on the horizontal axis in FIG. 5 means that the total opening area of the communication holes 52 approaches the total opening area of the suction holes 31 of the conveying belt 31. That is, in order to apply a negative pressure sufficient to stably convey the recording material 16 in the space D, a suction fan having a large air flow rate is used as compared with a case where the opening area ratio (α / β) is small. Necessary. In other words, when the opening area ratio (α / β) is small, a negative pressure sufficient to stably convey the recording material 16 is applied to the space D even if the air flow rate sucked by the suction fan is small. Therefore, a small fan can be employed. In particular, a smaller fan can be adopted by reducing the total opening area α of the communication holes 52.

  Furthermore, as described above, if the opening area ratio (α / β) is sufficiently small, no substantial suction force acts on the suction groove 50 while the recording material 16 is not on the conveyance belt 31, and therefore the conveyance belt. 31 wear can be suppressed.

Further, when the total opening area of the openings 51 of the suction groove 50 communicating with one space D is γ (unit: mm ² ), when α / γ <0.01, the transport belt is more reliably provided. 31 wear can be suppressed.

  Here, an arrow J in FIG. 5 indicates a range where the opening area ratio that can sufficiently suppress the sliding friction of the conveyance belt 31 is less than 1.0% (that is, α / β <0.01).

  Further, an arrow H in FIG. 5 indicates a range where the space D is a negative pressure having an absolute value of 200 Pa or more as a more preferable value for stably transporting the recording material 16 on the transport belt 31. When the recording material 16 is not on the conveyance belt 31, the space D is set to a negative pressure with an absolute value of 200 Pa or more, so that the conveyance device 30 conveys the recording material 16 while sucking it with a suction force of 200 Pa or more. be able to. Thereby, the flutter of the recording material 16 conveyed more reliably can be suppressed.

  That is, the area indicated by both arrows H and J is an area in which both the conveyance stability of the recording material 16 and the suppression of sliding friction of the conveyance belt 31 can be achieved.

As an example, the conveyance device 30 of the present embodiment is located in a region indicated by an arrow K in FIG. The recording material 16 is set to obtain an adsorption force of 5 g / cm ² . Specifically, the opening area ratio is 0.4 to 0.5%, the suction force is 500 Pa, the air flow rate by the suction fan 34 is 0.63 m ³ / min, and the width C in the transport direction of the suction groove 50 is 5.0 mm. The diameter A of the communication hole 52 was set to 1.1 mm.

[Example 2]
In the first embodiment, the total opening area (β) of the suction holes 31 of the conveyance belt 31 positioned on the openings 51 of the plurality of suction grooves 50 connected to one space D communicates with one space D. The case where the total opening area (γ) of the openings 51 of the suction grooves 50 is smaller (that is, β <γ) has been described. Therefore, in Example 1, the opening area ratio is represented by α / β.

  However, when the total opening area (γ) of the openings 51 of the suction grooves 50 communicating with one space D is equal to or less than the total opening area (β) of the suction holes 31a of the transport belt (γ ≦ β. )), The opening area ratio is a value representing α / γ as a percentage. That is, when γ ≦ β, the wear of the conveyor belt 31 can be suppressed by setting α <γ, more preferably α / γ <0.01.

  In Example 1, “the total opening area (β) of the suction holes 31 of the conveying belt 31 positioned on the openings 51 of the plurality of suction grooves 50 connected to the one space D” is defined as “one space D”. This can be understood as “the total opening area (γ) of the opening 51 of the suction groove 50 in communication”. The description related to the graph of FIG. 5 may be understood by replacing β with γ.

  Since other configurations are the same as those of the first embodiment, description thereof is omitted.

[Other configurations]
In the first and second embodiments, the conveying device 30 is applied to the fixing unit 11 in the electrophotographic image forming apparatus 100 as an example. However, the conveying device 30 may be applied to an inkjet image forming apparatus.

  In particular, in an ink jet type on-image forming apparatus in which ink moves in a space, if the recording material 16 flutters on the transport belt 31 or the position of the recording material 16 with respect to the transport belt 31 shifts, the ink dropping position shifts. , Will deteriorate the image quality. The recording material 16 can be transported more stably by being transported by the transport device 30 described above. In other words, the recording material 16 can be prevented from fluttering, and the recording material 16 can be prevented from being displaced due to the recording material 16 slipping on the conveying belt 31.

Reference Signs List 16 Recording Material 30 Conveying Device 31 Conveying Belt 31a Suction Hole 32 Flat Plate 33 Suction Base 34 Suction Fan 35 Drive Roller 36 Driven Roller 37 Driven Roller 37 Driven Roller 38 Driven Roller 50 Suction Groove 51 Opening D Space

Claims (19)

An endless belt having a plurality of holes, and a conveying belt for conveying a recording material;
A roller that is in contact with an inner peripheral surface of the conveyor belt and stretches the conveyor belt;
A suction section for sucking the recording material conveyed by the conveyance belt from the inside of the conveyance belt;
A conveying device comprising:
The suction part is
A suction chamber;
A fan for sucking air in the suction chamber;
A plurality of recesses having an opening that is open toward the inner peripheral surface side of the conveyor belt, and a communication port that is an opening having an opening area smaller than the opening and communicates with the suction chamber;
Have
The total opening area of the plurality of communication ports communicating with the suction chamber is α (unit: mm ² ), and the plurality of recesses communicating with the suction chamber among the plurality of holes of the transport belt has When the total opening area of the holes of the conveying belt positioned on the plurality of openings is β (unit: mm ² ), the plurality of communication ports communicating with the suction chamber are α / β < A conveying apparatus characterized by satisfying a relationship of 0.01.   The conveying apparatus according to claim 1, wherein an opening width of the communication port is 1.0 mm or more.   3. When the fan sucks the suction chamber in a state where there is no object to be transported on the transport belt, the suction chamber has a pressure that is 200 Pa or more lower than the recess. The conveying apparatus of Claim 1. When the total opening area of the openings of the plurality of recesses communicating with the suction chamber is γ (unit: mm ² ), the plurality of communication ports communicating with the suction chamber are α / The conveying apparatus according to claim 1, wherein a relationship of γ <0.01 is satisfied.   5. The transport apparatus according to claim 1, wherein an opening width of the plurality of concave portions in the recording material transport direction is 3.0 mm or greater and 30.0 mm or less. A plurality of the concave portions are provided in the width direction orthogonal to the recording material conveyance direction,
The first recess having the largest opening width in the width direction among the plurality of recesses provided in the width direction is located inside the region in which all the records that can be transported by the transport device can pass in the width direction. The conveying apparatus according to claim 1, wherein the conveying apparatus is provided in the apparatus.   The opening width in the width direction of a recess provided outside the region in the width direction among the plurality of recesses is smaller than the opening width of the first recess. The conveying apparatus as described in. An endless belt having a plurality of holes, and a conveying belt for conveying a recording material;
A roller that is in contact with an inner peripheral surface of the conveyor belt and stretches the conveyor belt;
A suction section for sucking the recording material conveyed by the conveyance belt from the inside of the conveyance belt;
A conveying device comprising:
The suction part is
A suction chamber;
A fan for sucking air in the suction chamber;
A plurality of recesses forming an opening on the inner peripheral surface side of the conveyor belt, and an opening having an opening area smaller than the opening and communicating with the suction chamber;
Have
The total opening area of the plurality of communication ports connected to the suction chamber is α (unit: mm ² ), and the total opening area of the openings of the plurality of recesses connected to the suction chamber is γ (unit : Mm ² ), the plurality of communication ports connected to the suction chamber satisfy a relationship of α / γ <0.01.   The conveying apparatus according to claim 8, wherein an opening width of the communication port is 1.0 mm or more.   10. The device according to claim 8, wherein when the fan sucks the suction chamber in a state where there is no object to be transported on the transport belt, the suction chamber has a pressure that is 200 Pa or more lower than the recess. The conveying apparatus of Claim 1.   11. The transport apparatus according to claim 8, wherein an opening width of the plurality of concave portions in the recording material transport direction is 3.0 mm or greater and 30.0 mm or less. A plurality of the concave portions are provided in the width direction orthogonal to the recording material conveyance direction,
The first recess having the largest opening width in the width direction among the plurality of recesses provided in the width direction is located inside the region in which all the records that can be transported by the transport device can pass in the width direction. The transport apparatus according to claim 8, wherein the transport apparatus is provided on the transport apparatus.   13. The opening width in the width direction of a recess provided outside the region in the width direction among the plurality of recesses is smaller than the opening width of the first recess. The conveying apparatus as described in. An image forming unit that forms an image of the liquid developer on a recording material using a liquid developer including a toner and a liquid carrier that is cured by ultraviolet rays;
An ultraviolet irradiation unit that irradiates the liquid developer image formed on the recording material by the image forming unit with ultraviolet rays;
An endless belt having a plurality of holes, wherein the recording material carrying an image of the liquid developer formed by the image forming unit is conveyed so as to pass through a region irradiated with ultraviolet rays by the ultraviolet irradiation unit. A transport belt for transporting, and
A roller that is in contact with an inner peripheral surface of the conveyor belt and stretches the conveyor belt;
A suction section for sucking the recording material conveyed by the conveyance belt from the inside of the conveyance belt;
An image forming apparatus having
The suction part is
A suction chamber;
A fan for sucking air in the suction chamber;
A plurality of recesses that form an opening that opens toward the inner peripheral surface side of the conveyor belt, and an opening that has an opening area smaller than the opening and communicates with the suction chamber;
Have
The total opening area of the plurality of communication ports communicating with the suction chamber is α (unit: mm ² ), and the plurality of recesses communicating with the suction chamber among the plurality of holes of the transport belt has When the total opening area of the holes of the conveying belt positioned on the plurality of openings is β (unit: mm ² ), the plurality of communication ports communicating with the suction chamber are α / β < An image forming apparatus satisfying a relationship of 0.01.   The image forming apparatus according to claim 14, wherein an opening width of the communication port is 1.0 mm or more.   16. When the fan sucks the suction chamber in a state where there is no object to be transported on the transport belt, the suction chamber has a pressure that is 200 Pa or more lower than the recess. The image forming apparatus according to claim 1.   The image forming apparatus according to claim 14, wherein an opening width of the plurality of concave portions in the recording material conveyance direction is 3.0 mm or more and 30.0 mm or less. A plurality of the concave portions are provided in the width direction orthogonal to the recording material conveyance direction,
Of the plurality of concave portions provided in the width direction, the first concave portion having the largest opening width in the width direction is configured such that all recording materials capable of image formation in the width direction are transported in the width direction. The image forming apparatus according to any one of claims 14 to 16, wherein the image forming apparatus is provided inside an area that can pass through when being conveyed by a belt.   The opening width in the width direction of the recess provided outside the region in the width direction among the plurality of recesses is smaller than the opening width of the first recess. The image forming apparatus described in 1.

Images