TW201836800A - Sheet production system, defibrator and sheet production device - Google Patents

Abstract

The present invention produces sheets in an office, etc., in which there is a demand for produced sheets. A sheet production system 1 comprises: a defibration unit 20; a fiber processing unit 40 for converting, into a portable form, the defibrated fibers that have been defibrated by the defibration unit 20; and a second device 100B for producing sheets S using the defibrated fibers in the portable form.

Description

Sheet manufacturing system, defibrating device, and sheet manufacturing device

The present invention relates to a sheet manufacturing system, a defibrating device, and a sheet manufacturing device.

A sheet manufacturing apparatus of a so-called wet-processed sheet in which a material containing a fiber is introduced into a liquid and the fiber is separated and reconstituted is known (for example, see Patent Document 1). Moreover, a dry sheet manufacturing apparatus which produces a sheet by defibrating a fiber-containing material in the air and decomposing the defibrated fiber as a raw material is known (for example, see Patent Document 2). [PRIOR ART DOCUMENT] [Patent Document 1] Japanese Patent Laid-Open Publication No. 2009-299231 (Patent Document 2)

[Problems to be Solved by the Invention] Since the device described in Patent Document 1 has a configuration of accumulating liquid or a structure for washing with water, the device is large in size, and a water supply and drainage device is required at the installation place. Since the device described in Patent Document 2 has a movable portion, it is difficult to arrange it in a place where vibration or noise is to be avoided as much as possible. For the above reasons, it is difficult to arrange the devices described in Patent Documents 1 and 2 in an office or the like. Further, in the apparatus described in Patent Documents 1 and 2, in the case of producing a sheet, since the material containing the fiber is defibrated, it takes time to manufacture the sheet, and it is difficult to manufacture the sheet as required. The present invention solves at least some of the above problems, and aims to produce a sheet in an office or the like that requires a sheet to be manufactured. [Means for Solving the Problems] In order to achieve the above object, the sheet manufacturing system of the present invention includes a defibrating unit that defibrates a material containing fibers, a sheet manufacturing unit that produces a sheet, and a processing unit that The defibrated fiber from which the defibration unit is defibrated is in a movable form, and the sheet manufacturing unit manufactures the sheet by using the disintegrated fiber of the movable form. According to the present invention, since the defibrated fiber can be easily conveyed, the sheet producing portion, the defibrating portion, and the treating portion can be separated. Therefore, the sheet can be manufactured in an office or the like where there is a sheet to be manufactured. Further, in the invention, the processing unit stores the defibrated fibers defibrated by the defibrating unit in a container. According to the present invention, the treatment of the defibrated fibers can be facilitated, and the defibrated fibers can be easily handled. Moreover, in the present invention, the processing unit processes the defibrated fibers defibrated by the defibrating unit into a shape retaining state. According to the present invention, since the treatment of the defibrated fiber becomes easy, the sheet can be produced in an office or the like where the sheet to be produced is required. Further, in the invention, the processing unit processes the defibrated fiber into any of a plate shape, a rectangular parallelepiped shape, and a spherical shape. According to this configuration, it is expected that the defibrated fibers can be easily moved together or can be easily placed in a cassette. Moreover, in the invention, the processing unit vacuum-packs the defibrated fiber. According to the present invention, the filling rate of the defibrated fibers can be efficiently improved, and the treatment of the defibrated fibers can be facilitated. Further, in the present invention, the disintegrated fiber of the transferable form may contain a binder. According to the present invention, it is not necessary to prepare a binder when the sheet is produced from the disintegrated fiber. Moreover, the present invention includes the first device having the defibrating unit and the second device having the sheet manufacturing unit. According to the present invention, since the second device can be disposed in another place, the sheet can be manufactured in an office or the like where the sheet to be manufactured is required. Further, in the invention, the first device and the second device can operate independently. According to the present invention, the degree of freedom in the arrangement and operation of the first device and the second device can be improved, and the sheet can be manufactured as needed. Moreover, in the invention, the sheet manufacturing unit has a printing unit that performs printing on the sheet. According to the present invention, the setting efficiency of the machine is improved as compared with the case of configuring a separate printing device. Further, in the invention, the sheet manufacturing unit manufactures the sheet by triggering a printing start instruction. According to the present invention, the sheet can be manufactured as needed according to the printing start instruction. Moreover, in the present invention, there is provided a third device which has coarsely crushed paper to obtain a coarse crushed portion of a raw material of the defibrated object. According to the present invention, the degree of freedom in arrangement and operation of the coarsely divided portion and the defibrated portion can be improved, and for example, the coarsely divided portion and the defibrated portion can be disposed at different places. Further, in the invention, the defibrating unit is a dry type. According to the present invention, it is not necessary to use a water supply and drainage device for defibration. Moreover, since water is not used, it is easy to process the fibers in a container or vacuum packaging. Further, in the invention, the defibrating unit is of a wet type. According to the invention, since the sheet manufacturing unit can be separated from the defibrating unit and the processing unit, the defibrating unit can be disposed in a place where the water supply and drainage device is provided. Further, it is easy to use a process in which the defibrated fiber contains moisture and the defibrated fiber is processed into a shape retaining state. Moreover, the defibrating device of the present invention includes a defibrating unit that defibrates a raw material containing fibers, and a processing unit that converts the defibrated fibers defibrated by the defibrating unit into a movable form. According to the present invention, since the defibrated fiber which is defibrated by the defibrating unit can be easily conveyed, the defibrating device can be disposed in a place other than an office or the like where the sheet to be manufactured is required. Moreover, the sheet manufacturing apparatus of the present invention has a supply port for supplying the defibrated fiber in a movable form, and a sheet manufacturing unit that produces a sheet by the defibrated fiber that is supplied to the supply port. According to the present invention, since the sheet can be produced by using the disintegrated fiber of the movable form, the sheet can be produced in an office or the like which is required to produce the sheet.

Hereinafter, preferred embodiments of the present invention will be described in detail using the drawings. The embodiments described below are not intended to limit the scope of the invention described in the claims. Further, not all of the configurations described below are essential components of the present invention. (First Embodiment) Fig. 1 is a view showing a configuration of a sheet manufacturing system 1 according to a first embodiment. The sheet manufacturing system 1 according to the present embodiment is preferably used, for example, by using a waste paper (sheet) such as a confined paper as a raw material, and then fibrillating it by dry defibration, followed by pressurization, heating, and cutting. A device for making new paper. It is also possible to improve the bonding strength or whiteness of the paper product, or the functions of color, aroma, flame retardance, etc., depending on the use, by mixing various additives with the fiber material. Further, by controlling the density, thickness, and shape of the paper, it is possible to manufacture paper of various thicknesses and sizes such as office paper or business card paper of A4 or A3 depending on the application. The sheet manufacturing system 1 is composed of a first device 100A and a second device 100B. The first device 100A and the second device 100B are separate devices that can be independently operated. The first device 100A is a device (also referred to as a coarse crushing, defibrating device, or a defibrating device) for producing a defibrated fiber by subjecting waste paper as a raw material to coarse crushing and defibration, and has a supply portion 10 and a coarse crushed product. The portion 12, the defibrating unit 20, the sorting unit 30, and the fiber processing unit 40. The second device 100B is a device (also referred to as a sheet manufacturing device and a sheet manufacturing unit) that manufactures a sheet from a defibrated fiber, and has a fiber supply unit 45, an additive mixing unit 50, a deposition unit 60, and a sheet. The forming portion 70 and the cutting portion 90 are formed. The supply unit 10 supplies the raw material to the coarse crushing portion 12. The raw material is only required to contain fibers. For example, paper, pulp, pulp sheets, cloths containing non-woven fabrics, or fabrics and the like are listed. In the present embodiment, a configuration in which waste paper is used as a raw material is exemplified. The supply unit 10 is an automatic input unit that has a tray (paper feed tray) on which, for example, waste paper is placed, and waste paper placed on the tray is continuously fed to the coarse-grained portion 12. The coarse crushing portion 12 (fine cut portion) is coarsely crushed (finely cut) by the coarse crushing blade 14 into coarse chips (hereinafter referred to as coarse crushed material). The coarse crushed material is in the same state as the shredded paper cut by a so-called shredder. The coarse crushing blade 14 is a blade for coarsely crushing the raw material in the air (in the air) or the like. The coarse crushing portion 12 is provided with a pair of rough cutting edges 14 which are sandwiched between the raw materials and coarsely crushed, and a driving portion that rotates the coarse crushing blades 14 and can be configured similarly to the so-called shredder. The shape or size of the coarse chips is arbitrary as long as it is suitable for the defibration treatment of the defibrating unit 20. For example, the coarse crushing portion 12 roughly pulverizes the raw material into a sheet of a size of 1 to several cm square or less. The raw material coarsely crushed by the coarse crushing portion 12 is received by the cylinder 1 and then transferred (transferred) to the defibrating portion 20 via the tube 2. The defibrating unit 20 defibrates the coarsely divided material from the coarsely divided portion 12. More specifically, the defibrating unit 20 defibrates the raw material (coarse material) coarsely crushed by the coarse crushing portion 12 to produce a defibrated fiber. Here, "defibration" means that a raw material (defibrated material) obtained by bonding a plurality of fibers is untwisted into one fiber. The defibrating unit 20 also has a function of separating the resin particles or the ink adhering to the raw material, the toner, the anti-seepage agent, and the like from the fibers. The person who passes through the defibrating unit 20 is referred to as "defibrillation material". In addition to the untwisted defibrating fiber, the "defleasing fiber" also includes a resin which separates the fiber from the fiber when the fiber is unwound (a resin for bonding a plurality of fibers to each other), a toner, a toner, and the like. Or the case of additives such as barrier agents and paper strength enhancers. The shape of the untwisted defibrated fiber is a string shape or a ribbon shape. The untwisted defibrated fiber may not exist in a state of being entangled with other untwisted defibrated fibers (independent state), or may be entangled with other unwrapped defibrated materials into a block state (formed so-called The "state of the mass" exists. The defibrating unit 20 defibrates in a dry manner. Here, the treatment of defibration or the like in the air (in the air) or the like instead of the liquid is referred to as a dry type. In the present embodiment, the defibrating unit 20 is configured to use an impeller pulverizer. Specifically, the defibrating unit 20 includes a rotor (not shown) that rotates at a high speed, and a sleeve (not shown) that is located on the outer circumference of the rotor. The coarse chips coarsely crushed by the coarse crushing portion 12 are interposed between the rotor and the sleeve of the defibrating portion 20 to be defibrated. The defibrating unit 20 generates an air flow by the rotation of the rotor. By the gas flow, the defibrating unit 20 can suck the raw material, that is, the coarse chips from the introduction port 22 of the tube 2, and transport the defibrated material to the discharge port 24. The defibrated material is sent from the discharge port 24 to the tube 3, and is transferred to the sorting unit 30 via the tube 3. Further, the airflow for transferring the defibrated material from the defibrating unit 20 to the sorting unit 30 may be the airflow generated by the defibrating unit 20, or an airflow generating device such as a blower may be provided, and the airflow may be utilized. The sorting unit 30 has an introduction port 32 through which the defibrated material including the defibrated fibers defibrated by the defibrating unit 20 flows into the tube 3 together with the air current. The sorting unit 30 sorts the defibrated materials introduced into the introduction port 32 in accordance with the length of the fibers. Specifically, the sorting unit 30 sets the defibrated material having a predetermined size or less in the defibrated material as the first sorting material, and divides the defibrated material larger than the first sorting material into the second sorting material. selected. The first sorting material contains smaller particles or the like in addition to the fiber, and the second sorting material includes, for example, a larger fiber, an undefibrated sheet (a coarse chip which is not sufficiently defibrated), and a defibrated fiber agglomerate. Or tangled masses, etc. In the present embodiment, the sorting unit 30 includes a drum portion 31 (screen portion), an outer casing portion 33 (cover portion) that houses the drum portion 31, and a first mesh forming portion 35. The drum portion 31 is a cylindrical sieve that is rotationally driven by a motor. The drum portion 31 has a mesh (filter, mesh) and functions as a sieve. According to the mesh, the drum portion 31 sorts the first sorting material smaller than the mesh opening degree (opening) and the second sorting material larger than the mesh opening degree. As the net of the drum portion 31, for example, a metal mesh, an expanded metal plate in which a metal plate with a slit is stretched, and a punched metal plate in which a press machine is equal to a metal plate to form a hole can be used. The defibrated material introduced into the introduction port 32 is conveyed to the inside of the drum portion 31 together with the air current, and the first sorting object is dropped from the mesh of the rotating cylinder portion 31 to the lower side by the rotation of the drum portion 31. The second sorting which cannot pass through the mesh of the drum portion 31 flows by the airflow flowing into the drum portion 31 from the introduction port 32, is guided to the discharge port 34, and is sent to the tube 8. The tube 8 connects the inside of the drum portion 31 with the tube 2. The second sorting material flowing through the tube 8 is supplied to the tube 2 together with the coarse chips coarsely shredded by the coarse crushing portion 12, and guided to the introduction port 22 of the defibrating portion 20. Thereby, the second sorting object is returned to the defibrating unit 20 to perform defibration processing. Further, the first sorting object sorted by the drum portion 31 is dispersed into the air by the mesh of the drum portion 31, and is directed to the mesh belt 36 of the first web forming portion 35 located below the drum portion 31. lower. The first mesh forming portion 35 (separating portion) includes a mesh belt 36 (separating belt), a roller 37, and a suction portion 38 (suction mechanism). The mesh belt 36 is a ring-shaped belt suspended from the three rollers 37, and is conveyed in the direction indicated by the arrow in the figure by the rotation of the rollers 37. The surface of the mesh belt 36 is formed by a mesh of openings of a particular size. The particles passing through the size of the mesh falling from the first sorting portion dropped from the sorting portion 30 fall below the mesh belt 36, and the fibers (defibrated fibers) which cannot pass through the mesh size are deposited on the mesh belt 36, and are meshed with the mesh belt. 36 Transfer in the direction of the arrow. The fine particles dropped from the mesh belt 36 include relatively small or low density (resin particles or toners or additives, etc.) in the defibration, and are not used in the sheet manufacturing system 1 when the sheet is manufactured. . The mesh belt 36 moves at a constant speed V1 during the normal operation of the first device 100A. Here, the normal operation refers to an operation other than the start of the first device 100A and the stop. Therefore, the defibrated material defibrated by the defibrating unit 20 is sorted into the first sorting and the second sorting in the sorting unit 30, and the second sorting is returned to the defibrating via the tube 4. Department 20. Further, the removed matter is removed from the first sorting material by the first mesh forming portion 35. The remainder after removing the removed material from the first sorting is a defibrated fiber suitable for the production of a sheet, and the defibrated fibers are deposited on the web tape 36 to form the first web W1. The suction portion 38 attracts air from below the mesh belt 36. By the attraction of the attraction portion 38, the formation of the first mesh W1 on the mesh belt 36 is promoted, and the removal of the removed matter is accelerated. Further, in the first device 100A, the configuration of sorting and separating the first defibrated material and the second defibrated material is not limited to the sorting unit 30 including the drum portion 41. For example, it is also possible to adopt a configuration in which the defibrated material to be defibrated by the defibrating unit 20 is classified by a classifier. As the classifier, for example, a cyclone classifier, an elbow jet classifier, and an Eddie classifier can be used. If such a classifier is used, the first and second sorts can be sorted and separated. Further, by the classifier described above, it is possible to realize a configuration in which a relatively small or low-density material (resin particles or toners or additives, etc.) in the defibration is separated and removed. The first device 100A includes a rotating body 39 that divides the first mesh W1 deposited on the mesh belt 36. The first web W1 is peeled off from the web 36 at a position where the web 36 is folded back by the roller 37 and is separated by the rotating body 39. The configuration of the rotating body 39 is arbitrary. However, in the present embodiment, it is possible to have a rotating blade shape having a plate-like blade and rotating. The rotating body 39 is disposed at a position where the first mesh W1 peeled from the mesh belt 36 is in contact with the blade. By the rotation of the rotating body 39 (for example, rotating in the direction indicated by the arrow R in the drawing), the blade is separated from the mesh belt 46 and the first mesh W1 conveyed by the blade collides and is divided and subdivided. Further, the rotating body 39 is disposed at a position where the blades of the rotating body 39 do not collide with the mesh belt 36. For example, the distance between the front end of the blade of the rotating body 39 and the mesh belt 36 can be set to 0. 05 mm or more and 0. 5 mm or less, In this case, The first mesh W1 can be effectively separated by the rotating body 39 without causing damage to the mesh belt 36.  The first web W1 separated by the rotating body 39 is supplied to the fiber processing unit 40 through the tube 7. The fiber processing unit 40 is a device that disposes the defibrated fiber into a movable form by performing a process of accommodating the first mesh W1 containing the defibrated fiber in the cassette 200 (container). A filling device for filling the defibrated fiber into the cassette 200 by an air blowing method, for example, may be applied to the fiber treating portion 40, Or a press-in device that presses (fills) the defibrated fibers into the cassette 200 by a conveyor belt such as a screw.  in this way, The first device 100A is configured to integrally include the following devices: Coarse crushing device, It will contain the raw material of the fiber, that is, the waste paper; Defibration device, It defibrates the coarsely divided material; And fiber treatment equipment, It stores the defibrated fiber in the cassette 200. the following, For the sake of convenience, When the first device 100A is functionally described, Properly expressed as "coarse, Defibration device".  The cassette 200 is a container that can be held without allowing the defibrated fibers filled into the interior to flow outward. It is easy for the user to carry. The cassette 200 can be a rigid metal container or a resin container. It can also be a container such as a flexible bag.  The fiber processing unit 40 has a discharge portion 42. The cartridge 200 for discharging the defibrated fibers is discharged from the outside. With this, The user can easily take out the cassette 200 and carry it to the second device 100B. another, The user is a person who uses the sheet manufacturing system 1, It may also be a person who uses only one of the functions of the sheet manufacturing system 1. E.g, The user is a person to be placed in the installation place of the first device 100A (a person who is working in an office, etc., which will be described later), Performing the operation of the sheet manufacturing system 1, maintenance, Management, etc. An operator who performs the installation of waste paper or the handling of defibrating fibers.  In this composition, Since the defibrated fiber is housed in the cassette 200, Therefore, it is possible to prevent the scattering of defibrating fibers while preventing And while suppressing the intrusion of foreign matter, Transfer the defibrated fibers. also, The pressure or negative pressure at which the defibrated fiber is stored (filled) to the cassette 200 can be set. It is easy to increase the filling rate of the defibrated fiber to the cassette 200. The pressure in this case is set to a value that does not cause an obstacle to the sheet manufacturing in the second device 100B. For example, the value of the defibrated fiber can be taken out by the fiber supply unit 45 which will be described later.  The fiber processing unit 40 may be a device (vacuum packaging device) that stores (fills) the defibrated fibers into the bag using a technique of vacuum packaging. In the case of vacuum packaging, The filling rate of the defibrated fiber can be further increased.  another, The fiber processing unit 40 is not limited to a device that stores the defibrated fibers in a container such as a cassette 200 or a bag. It is also possible to treat the defibrated fiber to a device having a shape retaining state. in particular, The fiber processing unit 40 can apply a compression processing device that compresses the defibrated fibers into a plate shape by a roller or the like. It is also possible to apply a method of compressing a defibrated fiber into a rectangular parallelepiped shape by a mold or the like, A compression molding device having a predetermined three-dimensional shape such as a spherical shape.  When the defibrated fiber is reinforced into a plate shape, Easy to stack and easy to move together. also, By reinforcing the defibrated fibers into a rectangular shape, a predetermined three-dimensional shape such as a ball shape, It is easy to put into a storage box such as a box. It is also easy to move together. In this case, By making it easy for the user to hold the shape by hand, And size, Easy to dismantle fiber handling, And a supply operation or the like to the supply port 46 of the second device 100B. When not using the cassette 200, Correspondingly, No need to carry out the relevant structure of the card 200, It is easy to simplify the composition. another, As long as the defibrated fiber is reinforced to a degree of shape retention, Not limited to the same method of strengthening the whole, It can only be partially reinforced (for example, only the outer perimeter). It is also possible to impart moisture for the purpose of reinforcement.  In the second device 100B, The fiber supply unit 45 has a supply port 46 to which a defibrated fiber of a movable form is supplied. When the defibrated fiber is stored in the cassette 200, The supply port 46 is configured to freely attach and detach the cassette 200. The fiber supply unit 45 takes out the disintegrated fiber in a movable form from the cassette 200 attached to the supply port 46, and discharges it to the tube 8.  The fiber supply unit 45 can be applied, for example, by means of air blowing or suction to discharge the defibrated fibers in the cassette 200. Or the device for defibrating the fiber in the cassette 200. also, The fiber supply portion 45 can also be applied to open the lower portion of the cassette 200, And the device for removing the defibrating fiber by gravity is used.  The fiber supply unit 45 preferably has a configuration in which the disintegrated fiber of the movable form is subdivided in order to facilitate mixing of the additive in the additive mixing unit 50. E.g, When the fiber supply portion 45 is in the case of defibrating the fibers in the cassette 200, Preferably, the defibrated fibers are broken and subdivided by scooping. also, When the fiber supply unit 45 discharges the defibrated fibers in the cassette 200 by air blowing or suction, The defibrated fibers can also be subdivided by a gas stream.  also, Without using the cassette 200, When the fiber processing unit 40 performs the above-described treatment to which the defibrated fiber is reinforced to have a shape retainability, The reinforced fibrillated fiber (the disintegrated fiber of the movable form) is put into the supply port 46. In this case, The fiber supply portion 45 can be used to unravel the reinforced fibrillated fibers. By using, for example, air supply or attraction, Or take out the defibrated fiber that has been invested, Or carry out belt transport, The defibrated fibers are discharged to the tube 8 by gravity.  The defibrated fiber discharged to the tube 8 is supplied to the additive mixing portion 50. The additive mixing unit 50 is provided with: Additive supply unit 52, Providing an additive comprising a resin; And a hybrid blower 56, This causes a flow of air in the tube 8 to flow the defibrated fibers discharged from the fiber supply portion 45 into the additive mixing portion 50.  In the additive mixing section 50, The air flow is generated by the mixing blower 56, And in the tube 9 connected to the downstream of the tube 8 and the mixing blower 56, The defibrated fiber is mixed while being mixed with the additive. also, Defibrating fiber in tube 8, The process of flowing in 9 is further solved, Made into a finer fibrous shape.  The additive supply unit 52 (resin storage unit) is connected to an additive cartridge (not shown) that accumulates the additive. The additive inside the additive cartridge is supplied to the tube 8. The additive cartridge can be configured to be detachably attachable to the additive supply unit 52. also, It may have a configuration in which the additive is added to the additive cartridge. The additive supply unit 52 is, for example, temporarily storing an additive containing fine powder or fine particles inside the additive cartridge. And the device for supplying the stored additive to the tube 8 using a screw feeder or the like.  The additive supplied from the additive supply unit 52 includes a resin such as a binder for bonding a plurality of fibers. The resin contained in the additive is a thermoplastic resin or a thermosetting resin. Such as AS resin, ABS resin, Polypropylene, Polyethylene, Polyvinyl chloride, Polystyrene, Acrylic, polyester resin, Polyethylene terephthalate, Polyphenylene ether, Polybutylene terephthalate, nylon, Polyamine, Polycarbonate, Polyacetal, Polyphenylene sulfide, Polyetheretherketone and the like. These resins may be used singly or in a suitable mixture. which is, Additives may contain a single substance, Can also be a mixture, A plurality of particles composed of various single or plural substances may also be included. also, The additive may be fibrous, It can also be in the form of a powder.  The resin contained in the additive adheres to the plurality of fibers by heating and melting. therefore, In a state in which the resin is mixed with the fiber, And in the state where the resin is not heated to the melting temperature, The fibers do not stick to each other.  also, The additive supplied from the additive supply unit 52 is in addition to the binder. According to the type of sheet produced, Containing a coloring agent to color the fibers, Or a coacervation inhibitor for inhibiting fiber aggregation or resin aggregation, A flame retardant for making fibers and the like difficult to burn. also, Additives that do not contain colorants can be colorless, Or a lighter color that appears to be colorless, It can also be white.  another, The mechanism for mixing the defibrated fiber with the additive is not particularly limited. Can be a blade stirrer by high speed rotation, It can also be used for the rotation of the container like a V-type mixer. These mechanisms may also be placed in front of or behind the mixing blower 56.  The deposition unit 60 deposits the defibrated material defibrated by the defibrating unit 20. More specifically, The stacking portion 60 introduces the mixture that has passed through the additive mixing portion 50 from the introduction port 62. Untangling the defibrated (defibrated fiber), Lower one side of the air in the air. Furthermore, When the resin of the additive supplied from the additive supply unit 52 in the deposition unit 60 is fibrous, Untie the entangled resin. With this, The deposition portion 60 allows the mixture to be uniformly deposited on the sheet forming portion 70 in a uniform manner.  The stacking portion 60 has a drum portion 61 (drum), And housing portion 63 (covering portion) of the drum portion 61. The drum portion 61 is a cylindrical sieve that is rotationally driven by a motor. The drum portion 61 has a net (filter, Wire mesh), And function as a sieve. With the mesh, The drum portion 61 passes fibers or particles smaller than the opening (opening) of the mesh, And the rotation of the tube portion 61 is lowered. The configuration of the drum portion 61 is the same as the configuration of the drum portion 31, for example.  another, The "screen" of the drum portion 61 may not have the function of sorting a specific object. which is, The "screen" used as the drum portion 61 means that the net is provided. The drum portion 61 can also lower the entire mixture introduced into the drum portion 61.  The sheet forming portion 70 has: The second mesh forming portion 71, Pressurizing unit 82, And a heating portion 84. The second mesh forming portion 71 is disposed below the drum portion 61. And stacking the passage that has passed through the stacking portion 60, The second web W2 (deposit) is formed. The second mesh forming portion 71 has: Net belt 72 (belt), Roller 74, And a suction mechanism 76.  The mesh belt 72 is a ring-shaped belt. Suspended from a plurality of rollers 74, And by the rotation of the roller 74, it is conveyed in the direction indicated by the arrow in the figure. The mesh belt 72 is made of, for example, metal. Resin, Cloth, Or not weaving, etc. The surface of the mesh belt 72 is constructed of a mesh of openings of a particular size. The particles passing through the size of the mesh in the fibers or particles lowered by the rotating cylinder portion 61 fall below the mesh belt 72, Fibers that cannot pass through the size of the mesh are stacked on the mesh belt 72. And the mesh belt 72 is conveyed in the direction of the arrow. The mesh belt 72 moves at a specific speed V2 during the operation of manufacturing the sheet.  The mesh of the mesh belt 72 is relatively small, It can be set to a size that does not allow most of the fibers or particles that are lowered by the rotating cylinder portion 61 to pass.  The suction mechanism 76 is disposed below the mesh belt 72 (opposite side of the stacking portion 60 side). The suction mechanism 76 can be attracted by a suction blower (not shown). A downward flow (air flow from the stacking portion 60 to the mesh belt 72) is generated.  By the suction mechanism 76, The mixture dispersed in the air by the stacking portion 60 can be attracted to the mesh belt 72. With this, The formation of the second mesh W2 on the mesh belt 72 can be promoted, And the discharge speed from the stacking portion 60 is increased. Furthermore, By the suction mechanism 76, The downward flow can be formed in the falling path of the mixture, It prevents the defibration or additives from becoming entangled in the fall.  As shown above, By passing through the stacking portion 60 and the second mesh forming portion 71 (mesh forming step), On the other hand, a second mesh W2 containing a large amount of air and being soft and bulky is formed. The second web W2 deposited on the mesh belt 72 is conveyed to the sheet forming portion 70.  In the transport path of the mesh belt 72, On the downstream side of the stacking portion 60, The air containing the mist is supplied by the humidifying unit 78. With this, The mist generated by the humidifying portion 78 is supplied to the second mesh W2, The amount of water contained in the second mesh W2 is adjusted. With this, The adsorption of the fibers to the mesh belt 72 due to static electricity can be suppressed.  The sheet forming unit 70 forms the second web W2 deposited on the mesh belt 72 and conveyed by the conveying unit 79 by pressurization and heating by the pressurizing unit 82 and the heating unit 84 to form the sheet S. By the fiber of the defibrated material contained in the second web W2, And adding heat to the additive, The plurality of fibers in the mixture are adhered to each other via an additive (resin).  The pressurizing portion 82 is composed of a pair of press rolls 85. The second web W2 is sandwiched by a specific nip and pressurized. The thickness of the second mesh W2 is reduced by the pressure, The density of the second web W2 is increased. One of the pair of press rolls 85 is a drive roll driven by a pressurizing unit drive motor (not shown). The other is a driven roller. The pressure roller 85 conveys the second web W2 having a high density by pressurization to the heating unit 84.  The heating portion 84 can use, for example, a heating roller (heater roller), Hot press forming machine, Heating plate, Warm air blower, Infrared heater, It is composed of a flashing fixer. In this embodiment, The heating unit 84 includes a pair of heating rollers 86. The heating roller 86 is provided by a heater disposed inside or outside. It is heated to a preset temperature. The heating roller 86 sandwiches the second web W2 pressurized by the pressing roller 85 and gives heat. The sheet shown by the symbol S in Fig. 1 is formed.  in this way, The second web W2 formed in the stacking portion 60 is pressurized and heated in the sheet forming portion 70. And become the sheet S.  One of the pair of heating rollers 86 is a driving roller driven by a heating unit driving motor (not shown). The other is a driven roller. The heating roller 86 conveys the heated sheet S to the cutting unit 90.  another, The number of the pressure rollers 85 provided in the pressurizing portion 82, The number of the heating rolls 86 provided in the heating unit 84 is not particularly limited.  The cutting portion 90 (cutting blade portion) cuts the sheet S formed by the sheet forming portion 70. In this embodiment, The cutting portion 90 has: The first cutting portion 92, The sheet S is cut in a direction crossing the conveying direction of the sheet S indicated by the symbol F in the drawing; And the second cutting unit 94, The sheet S is cut in a direction parallel to the conveying direction F. The second cutting portion 94 cuts, for example, the sheet S that has passed through the first cutting portion 92.  By cutting the portion 90, A single sheet S of a specific size such as A4 size is formed. The cut single sheet S is discharged to the discharge portion 96. The discharge unit 96 is provided with a paper discharge tray that discharges a sheet S of a specific size, Or stacking the stack of sheets S.  in this way, The second device 100B is configured to integrally include the following devices: Fiber supply device, It is supplied to the defibrated fiber in the cassette 200, That is, supplying the defibrated fiber in a movable form; And sheet manufacturing equipment (sheet manufacturing department), It manufactures sheet S using defibrated fibers. the following, For the sake of convenience, When the second device 100B is functionally described, It is expressed as "sheet manufacturing apparatus" as appropriate.  2 is a block diagram showing the constitution of a control system including the sheet manufacturing system 1.  The first device 100A has: Control device 101A, Operation unit 102A, Display unit 103A and remaining amount sensor 104A, And it can operate independently under the control of the control device 101A.  The control device 101A is a main processor, ROM (Read Only Memory: Read only memory) and RAM (Random Access Memory: A computer system composed of random access memory). The control device 101A controls the respective units of the first device 100A by the main processor executing the basic control program stored in the ROM (the supply unit 10, Rough part 12, Defibration unit 20, Sorting section 30, And the press-in portion 40). The operation unit 102A inputs various instructions to the first device 100A. The operation unit 103A has, for example, an operation switch or a touch panel.  After the control device 101A turns on the power of the first device 100A and executes the startup sequence, Each part of the first device 100A can be controlled. In this case, The control device 101A can receive the manufacturing start instruction of the first mesh W1 (defibrillation fiber) via the operation unit 102A. Manufacturing conditions (manufacturing amount of the first mesh W1, etc.), Input of the date of manufacture (schedule), etc. then, When the control device 101A is input with a manufacturing instruction, Or to the pre-set manufacturing start date, Each unit of the first device 100A is operated. With this, The first web W1 can be manufactured by coarsely crushing and de-firing the waste paper. The cassette 200 filled with the first web W1 is discharged.  The display unit 103A is under the control of the control device 101A, Various pieces of information related to the first device 100A are displayed. The display unit 103A is, for example, a liquid crystal display device. The remaining amount sensor 104A detects the remaining amount of the raw material (waste paper) in the first device 100A, The detection result is output to the control device 101A. The remaining amount sensor 104A is not limited to one, It can be plural. The remaining amount sensor 104A of the present configuration includes at least a sensor that detects the remaining amount of waste paper of the supply unit 10.  When the remaining amount sensor 104A detects that the remaining amount of the waste paper (raw material) remaining in the supply unit 10 is lower than the set value, the control device 101A We report the notification of insufficient paper waste. The notification processing is a display of the display unit 103A or a sound output by a sound output unit (not shown). another, The first device 100A communicates with an external device via a communication network (for example, a PC operated by a user (Personal Computer: PC)) When connecting, It is possible to notify the external device that the waste paper is insufficient (to replenish the supply unit 10 with waste paper).  also, It may in turn have a residual amount sensor that detects the remaining amount of coarse debris of the coarsely divided portion 12. In this case, When the remaining amount of the coarse debris is detected by the remaining amount sensor 104A, the control device 101A is lower than the set value. The waste paper can be supplied from the supply portion 10 to the coarse portion 12, It is coarsely crushed by the coarse crushing portion 12. By always ensuring coarse debris, At the beginning of the manufacture of the first mesh W1, The coarsely crushed material is immediately supplied to the defibrating section 20, The first mesh W1 can be quickly manufactured.  also, The control device 101A records the operation history of the first device 100A in a memory (not shown). Based on the operation history, measurement processing for measuring the amount of waste paper processed indicating the amount of fiber processing is performed. The operation history is, for example, the amount of waste paper supplied to the supply unit 10 (the number of sheets supplied), Information corresponding to the date of supply. also, In this composition, The control device 101A counts the amount of waste paper supply (the number of sheets supplied) of the supply unit 10 based on the operation history, This count value is recorded in the memory (not shown) as the waste paper processing amount.  The measurement process is not limited to this method, A method capable of measuring the amount of waste paper processed can be widely applied. E.g, Available to measure flow, a sensor such as weight or distance, Measuring the amount of defibrated fibers defibrated by the defibrating unit 20, The amount of coarse crushed material from the coarse crushed portion 12, The amount of manufacture of the first mesh W1, Or the amount of fiber filled into the cassette 200, The measurement result is taken as the waste paper processing amount. also, The number (number of times) of the cassettes 200 discharged from the first device 100A can be counted, The count result is taken as the amount of waste paper processed. The control device 101A can notify the user or the like of the amount of waste paper processing by displaying the amount of waste paper processing on the display unit 103A.  as shown in picture 2, The second device 100B is also the same as the first device 100A. With control device 101B, Operation unit 102B, Display unit 103B and remaining amount sensor 104B, And it can operate independently under the control of the control device 101B.  The control device 101B is a main processor, A computer system composed of a ROM and a RAM. The control device 101B controls the respective units of the second device 100B by the main processor executing the basic control program stored in the ROM (the fiber supply unit 45, Additive mixing unit 50, Stacking section 60, Sheet forming portion 70, And the cutting portion 90). The operation unit 102B inputs various instructions to the second device 100B. The operation unit 103B has, for example, an operation switch or a touch panel.  After the control device 101B turns on the power of the second device 100B and executes the startup sequence, Each part of the second device 100B can be controlled. In this case, The control device 101B can accept the manufacturing start instruction of the sheet S via the operation unit 102B, Manufacturing conditions (density (basis weight) of sheet S, Shape (size, thickness), colour, Manufacturing quantity (number of manufactured sheets), etc.) Input of the date of manufacture (schedule), etc. then, When the control device 101B inputs a manufacturing instruction, Or to the pre-set manufacturing start date, Each unit of the second device 100B is operated. With this, Sheet S is produced.  Here, The control device 101B adjusts the speed V2 of the mesh belt 72 of the sheet forming portion 70, for example. The density of the sheet S is controlled by at least one of the adjustment of the amount of fiber dropped by the rotating cylinder portion 61. also, The control device 101B controls the color of the sheet S by controlling the type and amount of the coloring agent added by the additive supply unit 52 (FIG. 1). also, The control device 101B controls the size of the sheet S by the cutting portion 90, The thickness of the sheet S is controlled by the pressurizing portion 82. With this, A sheet S corresponding to a predetermined manufacturing condition is manufactured.  The display unit 103B is under the control of the control device, Various pieces of information related to the second device 100B are displayed. The display unit 103B is, for example, a liquid crystal display device. The remaining amount sensor 104B detects the remaining amount of the raw material in the second device 100B, And/or the remaining amount of the manufactured sheet S, The detection result is output to the control device 101B. The remaining amount sensor 104B of the present configuration includes at least the remaining amount of the remaining amount of the first mesh W1 (defibrillation fiber) (hereinafter referred to as the remaining amount of the cassette 200) detected in the cassette 200 of the fiber supply unit 45. Quantity sensor.  When the remaining amount of the cassette 200 is detected by the remaining amount sensor 104B, the control device 101B is lower than the set value. A notification process of not reporting that the remaining amount of the card 200 is insufficient is performed. The notification processing is a display of the display unit 103B or a sound output by a sound output unit (not shown). another, When the second device 100B is connected to an external device via a communication network, The external device can be notified that the fiber (raw material) is insufficient (replacement of the cassette 200).  also, Further, it may have a remaining amount sensor that detects the remaining amount of the sheet S remaining in the discharge portion 96. In this case, When the remaining amount of the sheet S remaining in the discharge portion 96 is detected by the remaining amount sensor, the control device 101B is lower than the set value, It is possible to perform notification processing for notifying the shortage of the sheet S. The notification processing can be displayed, as described above. The sound is output or notified to an external device.  also, The control device 101B records the operation history of the second device 100B in a memory (not shown). And measuring the sheet manufacturing amount indicating the fiber processing amount based on the operation history. The course of action is, for example, information that associates the number of sheets produced by the sheet S with the date of manufacture. also, In this composition, The control device 101B counts the manufacturing amount (the number of sheets manufactured) of the sheet S based on the operation history, This count value is recorded in a memory (not shown) as a sheet manufacturing amount. The control device 101B can notify the user or the like of the sheet manufacturing amount by displaying the sheet manufacturing amount on the display unit 103A. another, Instead of measuring the number of sheets produced by the sheet S, And measuring the amount of fiber taken out of the cassette 200, Or the amount of manufacture of the second web W2.  As mentioned above, Since the first device 100A and the second device 100B can operate independently, Therefore, it is not necessary to be placed in the same place. also, The first device 100A and the second device 100B are configured by a dry type that does not require large-scale water equipment. With this, And by putting the raw material containing the fiber into the water, Compared with the case where the fiber is dissociated and reconstituted into a wet type (wet paper making method, etc.) No need for water related equipment, Or simplistic, And the degree of freedom in the configuration place is increased.  E.g, The second apparatus 100B which is a sheet manufacturing apparatus can be disposed in an office where the sheet S is required. Will be coarsely crushed, The first device 100A, which is the defibrating device, is disposed in the back field (see FIG. 2). Express this configuration as configuration style A.  The office is the main area for business operations. The backcourt is an area that is not dominated by business operations. Such as warehouses, Workplace. In the office, there is a relatively large area in which the printing apparatus used for the sheet S as a printing medium has a relatively large number of mechanical parts in which the sheet S is required.  When configuring style A, The user brings the waste paper generated by the office and the like into the backcourt. It is attached to the supply unit 10 of the first device 100A. then, The user manufactures the first mesh W1 by coarsely breaking and defibrating the waste paper by operating the first device 100A. The cassette 200 filled with the first web W1 is discharged. E.g, The user installs the confidential file of the processing object (hereinafter referred to as confidential paper) on the first device 100A. Further, by operating the apparatus 100A, it is assumed that the confidential paper cannot be read immediately.  in this way, The user processes the waste paper in the back field, And dismantle the fiber into the raw material of the sheet S. also, It can avoid the occurrence of vibration or noise accompanying coarse crushing and defibration in the office.  then, The user carries the cassette 200 and moves to the office. The cassette 200 is attached to the fiber supply unit 45 of the second device 100B. then, The user can manufacture the sheet S by using the first web W1 in the cassette 200 as a raw material by operating the second apparatus 100B.  Subsequently, The user can start printing the sheet S by attaching the manufactured sheet S to an office printing device (not shown). which is, The sheet S required for printing can be produced as needed. another, When the discharge unit 96 of the second device 100B has the manufactured sheet S, If the sheet S is mounted on a printing device, It does not generate waiting time until the sheet S is manufactured. The user can use the sheet S for printing.  With this, Recycling waste paper produced by the office, etc. And handle confidential paper.  In configuration style A, The second device 100B, which is a sheet manufacturing apparatus, is disposed in an office that uses the sheet S, that is, an office. Therefore, it is easy for the user to use the sheet S. also, Since the first device 100A that performs coarse crushing and defibration is disposed in the back field, Therefore, compared with the case where the first device 100A is placed in the office, Vibration or noise accompanying coarse crushing and defibration will not be a problem. also, Since waste paper such as confidential paper is moved between the office and the backcourt, Therefore, compared with the situation of relying on external recycling companies to dispose of waste paper, Helps prevent confidential leaks.  therefore, Configuration style A can schedule the manufactured sheet S in the office. Avoid situations where vibration or noise accompanying coarse crushing and defibration occurs in the office.  another, The field after the configuration of the sheet manufacturing system 1 may also be part of the office. E.g, Widely applicable areas where the printing device is relatively small or the printing device does not exist, Or use a relatively small area of the sheet S. E.g, When dividing the office space constituting one of the buildings into a plurality of areas, The first device 100A is disposed in a region where the demand for the sheet S in each region is relatively high, The second device 100B is disposed in a region where the demand for the sheet S is relatively low.  also, Not limited to configuration style A, It can also be configured other than configuration style A. Fig. 3 is a view showing an example of a plurality of configuration patterns.  The arrangement pattern B shown in FIG. 3 arranges the first device 100A and the second device 100B in the office. In this case, The user crushes and defoams waste paper such as confidential paper by the first device 100A disposed in the office. therefore, The confidential paper will not be taken out of the office and can be set to be unreadable. It is good for preventing leakage of confidentiality. Furthermore, When the user needs the sheet S, No need to move from the office, On the other hand, the sheet S is manufactured as needed by the second device 100B.  E.g, The user stores the cassette 200 discharged from the first device 100A, Once the raw material of the second device 100B, that is, the defibrating fiber is insufficient, The stored cassette 200 is attached to the second device 100B. With this, Waste paper recycling can be done only in the office.  also, Since the first device 100A and the second device 100B operate independently of each other, Therefore, each device 100A, The 100B is deployed in different locations within the office. E.g, The first device 100A can be disposed in a place away from the user in the office. The second device 100B is disposed in an arrangement close to a user or a printing device. In this case, The vibration and noise of the first device 100A are not easily affected by the user. also, The user can schedule the sheet S from the nearby second device 100B.  in this way, Configuring style B helps to prevent confidential leakage. On the one hand, it is possible to schedule the sheet S manufactured by the office. another, The configuration of the configuration pattern B is more suitable for reducing the noise and vibration to the extent that the first device 100A can be used in the office. Or in the office where vibration or noise is not a problem.  The configuration pattern C shown in FIG. 3 is that the first device 100A is disposed in the office. The second device 100B is placed in the back field. In this case, Same as configuration style B, The user does not take the confidential paper out of the office and can be made unreadable. It is good for preventing leakage of confidentiality. also, The cassette 200 containing the defibrated fibers obtained by the first apparatus 100A is carried into the back field by the user.  And, The user moves to the back field when the sheet S is manufactured, The cassette 200 containing the defibrated fibers is dispatched. then, The user can install the defibrated fiber in the second device 100B disposed in the rear place. The second device 100B is actuated to manufacture the sheet S.  in this way, Configuration style C is more suitable for one side to prevent confidential leakage. Reduce the space in the office, Or use the backcourt effectively.  As explained above, The sheet manufacturing system 1 has: Defibration unit 20; Fiber processing unit 40, The fibrillated fiber defibrated by the defibrating unit 20 is in a movable form; And the second device 100B (sheet manufacturing unit), The sheet S is produced by using a disintegrated fiber of a movable form. Since the defibrated fiber is made into a movable form, Therefore, the second device 100B can be It is separated from the defibrating unit 20 and the fiber processing unit 40. therefore, The second device 100B can be easily And/or the defibrating unit 20 or the like is disposed in an office or the like which generates waste paper which is a raw material and which is required to be manufactured.  E.g, When the vibration or noise of the defibration is so large that it becomes a problem in the office, Only by disposing the second device 100B in the office, The vibration or noise of defibration is not generated in the office. also, When the vibration or noise of the defibration is relatively small, It is possible to arrange the second device 100B in the office. Further, the defibration unit 20 is placed in a place where vibration or noise in the office is less likely to be a problem.  also, The fiber processing unit 40 stores the defibrated fibers in a container such as a cassette 200 or a bag. Therefore, the processing of defibrating fibers can be facilitated. It is easy to handle defibrating fibers.  also, When the fiber processing unit 40 processes the defibrated fiber to have a shape retaining state, No need to carry a container such as 200, Therefore, it is easy to simplify the device configuration. In this case, By treating the defibrated fibers into a plate shape, Rectangular shape, In any state of the ball shape, it is expected that it is easy to move the defibrating fiber together. another, When the defibrated fiber is stored in a container such as a cassette 200 or a bag, The defibrated fiber can also be processed into a plate shape, Rectangular shape, Any state of the ball shape. In this case, It is expected to be easy to put into the effect of the cassette 200. also, The shape of the container can be a plate shape, Rectangular shape, Any state of the ball shape.  also, When the fiber processing unit 40 vacuum-packs the defibrated fiber to form a movable form, It can efficiently increase the filling rate of defibrated fibers, And easy to dismantle fiber treatment. Here, Since the defibrating unit 20 is dry, Therefore, it is not necessary to have water supply and drainage equipment for defibration. also, Since no moisture is used, Therefore, compared with the case where the defibrating unit is wet, The defibrated fiber is stored in a container such as a cassette 200, Or vacuum packaging process is relatively easy.  another, The aspect in which the defibrated fiber is in a movable form is not limited to the above embodiment. E.g, The fiber can be supplied to the fiber processing unit 40 by the binder fiber containing the binder for bonding the fibers. The disintegrating fiber of the movable form contains a binder. With this, It is not necessary to prepare a binder for the second device 100B. also, The disintegrated fiber of the movable form can be made of materials other than the binder. Such as coloring agents, Coagulation inhibitor, Flame retardant, etc. E.g, A part or all of the configuration of the additive supply unit 52 may be provided on the upstream side of the fiber processing unit 40 (ie, First device 100A).  also, Since the sheet manufacturing system 1 is composed of the first device 100A having the defibrating unit 20, It is constituted by the second device 100B that manufactures the sheet S, Therefore, the second device 100B can be placed in an office or the like. Further, the first device 100A is disposed in a place where the vibration or noise of the defibration does not become a problem.  And, Since the first device 100A and the second device 100B can operate independently, Therefore, the freedom of configuration and operation of the devices can be improved. And manufacture sheets as needed.  (Second Embodiment) Fig. 4 is a block diagram showing a configuration of a control system including a sheet manufacturing system 1 according to a second embodiment.  The second embodiment has, instead of the first device 100A of the first embodiment,: The first device 110A having the defibrating unit 20, And the third device 110C having the coarse portion 12. another, The same portions as those in the first embodiment are denoted by the same reference numerals, and their description will be omitted. And describe the different parts in detail.  The third device 110C has: Supply unit 10, The coarse crushing portion 12 and the coarse scrap processing portion 40A. The coarse-grain processing portion 40A fills the coarse crushed material of the coarse crushed portion 12 into the cassette 210 (container). And discharged to the discharge portion 42A. The coarse-grain processing unit 40A and the discharge unit 42A have substantially the same configuration as the fiber processing unit 40 and the discharge unit 42 described above. the following, For the sake of convenience, In the case where the third device 110C is functionally described, it is appropriately expressed as a "coarse device".  also, The third device 110C has: Control device 111C, Operation unit 112C, Display portion 113C and remaining amount sensor 114C, And it can operate independently under the control of the control device 111A. The control device 111C is a main processor, A computer system composed of a ROM and a RAM. The control device 111C controls the respective units of the third device 110C by the main processor executing the basic control program stored in the ROM (the supply unit 10, Rough part 12, Crushed material processing unit 40A). The operation unit 112C inputs various instructions to the third device 110C.  After the control device 111C turns on the power of the third device 110C to execute the startup sequence, Each part of the third device 110C can be controlled. In this case, The control device 111C can accept the manufacturing start instruction of the coarse crushed material via the operation unit 112C, Manufacturing conditions (manufacture amount of coarse crushed material, etc.), Input of the date of manufacture (schedule), etc. then, When the control device 111C is input with a manufacturing instruction, Or to the pre-set manufacturing start date, The respective units of the third device 110C are operated, Thereby, the waste paper is coarsely crushed and discharged from the cassette 210 filled with coarse debris.  The display unit 113C is under the control of the control device 111C, Various pieces of information related to the third device 110C are displayed. The remaining amount sensor 114C detects the remaining amount of the raw material (waste paper) in the third device 110C, The test result is output to the control device. The remaining amount sensor 114C is not limited to one, It can be plural. The remaining amount sensor 114C of the present configuration includes at least a sensor that detects the remaining amount of waste paper of the supply unit 10.  When the remaining amount of the waste paper remaining in the supply unit 10 is detected by the remaining amount sensor 114C, the control device 111C is lower than the set value. We report the notification of insufficient paper waste. The notification processing is a display of the display unit 113C or a sound output by a sound output unit not shown. another, When the third device 110C is connected to an external device (for example, a PC operated by a user) via a communication network, It is possible to notify the external device that the waste paper is insufficient (to replenish the supply unit 10 with waste paper).  also, The control device 111C records the operation history of the third device 110C in a memory (not shown). Based on the operation history, measurement processing for measuring the amount of waste paper processed indicating the amount of fiber processing is performed. The operation history is, for example, information that associates the amount of waste paper supply (the number of sheets supplied) of the supply unit 10 with the time of supply. also, In this composition, The control device 111A counts the amount of waste paper supply (the number of sheets supplied) of the supply unit 10 based on the operation history, This count value is recorded in the memory (not shown) as the waste paper processing amount. another, The measurement process is not limited to this method, A method capable of measuring the amount of waste paper processed can be widely applied. The control device 111C can notify the user or the like of the amount of waste paper processing by displaying the amount of waste paper processing on the display unit 113C.  The first device 110A has: Crushed material supply unit 45A, Defibration unit 20, Sorting section 30, And the fiber processing unit 40. The coarse scrap supply unit 45A has a supply port 46A for freely loading and unloading the cassette 210, And removing the coarse debris from the cassette 210 mounted on the supply port 46A, And supplied to the defibrating unit 20. Defibration unit 20, Sorting section 30, The fiber processing unit 40 is the same as the first device 100A of the first embodiment. the following, For the sake of convenience, In the case where the first device 110A is functionally described, it is appropriately expressed as a "defibating device".  also, The first device 110A has: Control device 111A, Operation unit 112A, Display portion 113A and remaining amount sensor 114A, And it can operate independently under the control of the control device 111A. The control device 111A is a main processor, A computer system composed of a ROM and a RAM. The control device 111A controls each unit of the first device 110A by the main processor executing the basic control program stored in the ROM (the coarse material supply unit 45A, Defibration unit 20, Sorting section 30, Fiber treatment unit 40). The operation unit 112A inputs various instructions to the first device 110A.  The control device 111A performs the startup sequence after the power of the first device 110A is turned on. Each part of the first device 110A can be controlled. In this case, The control device 111A can receive the manufacturing start instruction of the first mesh W1 (defibrillation fiber) via the operation unit 112A. Manufacturing conditions (manufacturing amount of the first mesh W1, etc.), Input of the date of manufacture (schedule), etc. then, When the control device 111A inputs a manufacturing instruction, Or to the pre-set manufacturing start date, The respective units of the first device 110A are operated, Thereby, the waste paper is coarsely crushed to manufacture the first mesh W1, The cassette 200 filled with the first web W1 is discharged.  The display unit 113A is under the control of the control device 111A, Various pieces of information related to the first device 110A are displayed. The remaining amount sensor 114A detects the remaining amount of the fiber as the raw material in the first device 110A, The detection result is output to the control device 111A. The remaining amount sensor 114A detects, for example, the remaining amount of the coarse crushed matter installed in the cassette 210 of the coarse scrap supply portion 45A.  When the remaining amount sensor 114A detects that the remaining amount of the coarse debris in the first device 110A is lower than the set value, the control device 111A A notification process for notifying the shortage of coarse debris (for example, replacing the cassette 210) is performed. The notification processing is a display of the display unit 113A or a sound output by a sound output unit (not shown). another, When the first device 110A is connected to an external device (for example, a PC operated by a user) via a communication network, The external device can be notified that the coarse debris is insufficient.  also, The control device 111A records the operation history of the first device 110A in a memory (not shown). Based on the operation history, measurement processing for measuring the amount of waste paper processed indicating the amount of fiber processing is performed. The course of action is, for example, the amount of defibrated fiber to be defibrated by the defibrating unit 20, Correspond to the date of defibration. also, In this composition, The control device 111A counts the amount of defibrated fibers based on the operation history. This count value is recorded in the memory (not shown) as the waste paper processing amount. another, The amount of defibrated fiber can be measured by measuring the flow rate, Sensor measurement of weight or distance, etc. also, The amount of manufacture of the first web W1, Or the amount of fibers filled into the cassette 200 is measured as the amount of defibrated fiber (waste paper processing amount). The control device 111A can notify the user or the like of the amount of waste paper processing by displaying the amount of waste paper processing on the display unit 113A.  The second device 100B is the same as the first embodiment.  In this embodiment, Since the first device 110A constituting the sheet manufacturing system 1, The second device 100B and the third device 110C can each operate independently. Therefore, it is not necessary to be placed in the same place. also, Each device 110A, 100B and 110C are made up of dry equipment that does not require large-scale water equipment. Therefore, compared with the case of being wet No need for water related equipment, Or simplistic, And easy to set up to the office and so on.  E.g, The second device 100B, which is a sheet manufacturing apparatus, is placed in an office having a sheet S demand. The coarse crushing device, that is, the third device 110C, is also disposed in an office that produces waste paper of coarsely crushed objects. also, The defibrating device, that is, the first device 110A, is disposed in the back field (Fig. 4). Express this configuration as configuration style D.  When configuring style D, The user can crush the waste paper such as confidential paper by the third device 110C disposed in the office. therefore, The confidential paper will not be taken out of the office and can be set to be unreadable. It is good for preventing leakage of confidentiality. also, The coarse debris obtained by the third device 110C is carried into the back field by the user or the like.  With this, The user dispatches a cassette 210 containing coarse debris in the back field. The cassette 200 containing the defibrated fibers can be obtained by the second device 110B disposed in the back field. In this case, Due to defibration in the back field, Therefore, it is avoided to cause vibration or noise accompanying defibration in the office.  then, The user can carry the cassette 200 containing defibrated fibers obtained in the backcourt and move to the office. The sheet S is produced by the second device 100B disposed in the office. The user can immediately start printing onto the sheet S by mounting the manufactured sheet S to the printing device of the office.  In configuration style D, Because the waste paper such as confidential paper is coarsely broken in the office, And it helps to prevent leakage of confidentiality. And because the sheet S is made in the office, Therefore, it is easy to manufacture the sheet S as required. It is easy to seek the printing and utilization of the sheet S. also, Due to defibration in the back field, Therefore, it is possible to avoid the occurrence of vibration or noise accompanying defibration in the office.  Since the general dry defibration uses an impeller grinder or the like, Therefore, it is easier to increase vibration or noise than in the case of coarse crushing. In configuration style D, It can avoid the impact of vibration or noise on the office due to defibration. Improve the convenience of users in the office.  Fig. 5 is a view showing an example of a plurality of configuration patterns.  The configuration pattern A' shown in FIG. 5 is composed of two devices 100A, The configuration pattern A when 100B constitutes the sheet manufacturing system 1 is similar. which is, The second device 100B, which is a sheet manufacturing apparatus, is placed in the office. The third device 110C and the first device 110A that perform coarse crushing and defibration are disposed in the back field.  According to the configuration style A', In addition to the effect obtained by configuring style A, Since there are 2 devices installed in the backcourt, Therefore, the freedom of configuration and operation in the backcourt is improved. also, Since the third device 110C is easier to start up than the first device 110A, stop, Therefore, it is possible to immediately crush coarse paper and the like. therefore, Helps prevent leakage of confidentiality.  also, The configuration pattern E shown in FIG. 5 arranges the coarse crushing device, that is, the third device 110C, in an office that produces waste paper of coarsely crushed objects. The first device 110A, which is the defibrating device, and the second device 100B, which is the sheet manufacturing device, are placed in the back field.  When configuring the style E, The user can crush the waste paper such as confidential paper by the third device 110C disposed in the office. It is good for preventing leakage of confidentiality. also, The coarse debris obtained by the third device 110C is carried into the back field by the user or the like.  The user can schedule coarse debris in the backcourt. The defibrated fiber which becomes the raw material of the sheet S is obtained by the second device 110B disposed in the back field. Since the back field is also provided with the second device 100B which is a sheet manufacturing device, Therefore, the defibrated fiber can be easily attached to the second device 100B to manufacture the sheet S. therefore, The user can easily schedule the sheet S in the back field.  Configuration style E helps prevent leakage of confidentiality. And in the back field for defibration and sheet manufacturing, Therefore, vibration or noise accompanying defibration will not occur in the office.  also, The configuration pattern C' shown in Figure 5, With two devices 100A, The configuration pattern C when 100B constitutes the sheet manufacturing system 1 is similar. which is, The third device 110C and the first device 110A, which are the coarse crushing devices, are disposed in the office. The second device 100B, which is a sheet manufacturing apparatus, is placed in the back field.  According to the configuration style C', In addition to the effect obtained by configuring style C, Since there are 2 units installed in the office, Therefore, the freedom of configuration and operation in the office is increased. which is, The third device 110C can be disposed at a place where waste paper is produced in the office. Further, the first device 110A is disposed in a place where the influence of vibration or noise in the office is small.  (Third Embodiment) Fig. 6 is a block diagram showing the configuration of a control system including a sheet manufacturing system 1 according to a third embodiment.  The third embodiment differs from the second embodiment in that: The first device 110A and the second device 100B of the second embodiment are configured by one device (hereinafter, the fourth device) 120A. another, The same portions as those in the above embodiments are denoted by the same reference numerals, and their description will be omitted. And describe the different parts in detail.  The fourth device 120A has: Crushed material supply unit 45A, Defibration unit 20, Sorting section 30, Additive mixing unit 50, Stacking section 60, Sheet forming portion 70, And the cutting portion 90. which is, The fourth device 120A functions as a device for performing defibration and sheet production. the following, For the sake of convenience, In the case of functionally describing the fourth device 120A, Properly stated as "defibration, Sheet manufacturing device".  also, The fourth device 120A has: Control device 121A, Operation unit 122A, Display portion 123A and remaining amount sensor 124A, And it can operate independently under the control of the control device 121A. The control device 121A is a main processor, A computer system composed of a ROM and a RAM. The control device 121A controls the respective units of the fourth device 120A by the main processor executing the basic control program stored in the ROM (the coarse material supply portion 45A, Defibration unit 20, Sorting section 30, Additive mixing unit 50, Stacking section 60, Sheet forming portion 70, And the cutting portion 90). The operation unit 122A inputs various instructions to the fourth device 120A.  After the control device 121A turns on the power of the fourth device 120A and executes the startup sequence, Each part of the fourth device 120A can be controlled. In this case, The control device 121A can accept the manufacturing start instruction of the sheet S via the operation unit 122A, Manufacturing conditions (density (basis weight) of sheet S, Shape (size, thickness), colour, Manufacturing quantity (number of manufactured sheets), etc.) Input of the date of manufacture (schedule), etc. then, When the control device 121A inputs a manufacturing instruction, Or to the pre-set manufacturing start date, The respective units of the fourth device 120A are operated, Thereby dissolving the coarse debris in the cassette 210, The sheet S corresponding to the manufacturing conditions is produced from the defibrated fibers.  The display unit 123A is under the control of the control device 121A, Various pieces of information related to the fourth device 120A are displayed. The remaining amount sensor 124A detects the raw material in the fourth device 120A, And/or the remaining amount of the manufactured sheet S, The detection result is output to the control device 121A. The remaining amount sensor 124A of the present configuration detects, for example, the remaining amount of the coarse debris contained in the cassette 210 of the coarse-grain supply unit 45A.  When the remaining amount of the coarse debris in the fourth device 120A is lower than the set value, the control device 121A A notification process for notifying the shortage of coarse debris (for example, replacing the cassette 210) is performed. The notification processing is a display of the display unit 123A or a sound output by a sound output unit (not shown). another, When the fourth device 120A is connected to another device (for example, a PC operated by a user) via a communication network, Other devices can be notified that the coarse debris is insufficient.  also, The control device 121A records the operation history of the fourth device 120A in a memory (not shown). And measuring the sheet manufacturing amount indicating the fiber processing amount based on the operation history. The course of action is, for example, information that associates the number of sheets produced by the sheet S with the date of manufacture. also, In this composition, The control device 121A counts the manufacturing amount (the number of sheets manufactured) of the sheet S based on the operation history, This count value is recorded in a memory (not shown) as a sheet manufacturing amount. The control device 121A can notify the user or the like of the sheet manufacturing amount by displaying the sheet manufacturing amount on the display unit 123A. another, An alternative method of measuring the number of sheets produced by the sheet S, And measuring the amount of coarse debris taken out from the cassette 210, Or the amount of manufacture of the second web W2.  E.g, Disposing the coarse crushing device, that is, the third device 110C, in the office. Will be defibrated, The fourth device 120A, which is a sheet manufacturing apparatus, is disposed in the back field (see FIG. 6). This configuration is expressed as a configuration style E'.  Configure the style E', With 3 units 110C, 110A, The arrangement pattern E when 100B constitutes the sheet manufacturing system 1 is similar.  When configuring the style E', The user can crush the waste paper such as confidential paper by the third device 110C disposed in the office. It is good for preventing leakage of confidentiality. also, The coarse debris generated by the third device 110C is carried into the back field by the user or the like.  The user can schedule coarse debris in the backcourt. The sheet S is produced by the fourth device 120A disposed in the back field. With this, The same effect as the configuration style E can be obtained. which is, Helps prevent leakage of confidentiality, And because of the defibration and sheet manufacturing in the back field, Therefore, it is possible to obtain an effect that does not cause vibration or noise accompanying defibration in the office.  (Fourth Embodiment) Fig. 7 is a view showing a schematic configuration of a sheet manufacturing system 1 according to a fourth embodiment.  The fourth embodiment can be used in a plurality of offices X1. X2 Sheet S was produced in X3. the following, The difference from the first embodiment will be described.  The second apparatus 100B, which is a sheet manufacturing apparatus, is disposed in the office X1. X2 X3 each. also, Coarse, The defibrating device, that is, the first device 100A, is disposed in the back field. which is, The fourth embodiment is an arrangement corresponding to the above-described arrangement pattern A.  At office X1 X2 Each of X3 is equipped with a recycling box 11 for recycling waste paper in each office. Further, it is disposed in each office as a coarse crushing portion 12X that functions as a shredder for cutting waste paper. The coarse crushing portion 12X is a device capable of separately crushing waste paper. Further, for example, the configuration is the same as that of the coarsely divided portion 12 in the first device 100A.  As shown in Figure 7, In the first device 100A, As shown by the arrow in Figure 7, The settings are supplied and recycled to each office X1 X2 The supply port 12K of the waste paper of the recovery box 11 of X3. The supply port 12K is a portion for supplying waste paper to the coarse crushing portion 12. which is, Office X1 X2 The user of X3 or the like can carry the waste paper to the back field and put it into the supply port 12K. Further, the first device 100A is actuated to obtain a defibrated fiber which is a raw material of the sheet S.  In each office X1 X2 The X3 is equipped with a coarsely shredded part 12X that can be operated separately. Therefore, it is also possible to crush waste paper such as confidential paper in the office. It is good for preventing leakage of confidentiality. E.g, Waste paper with low confidentiality can be placed in the recycling box 11 of the office and coarsely crushed in the back field. on the other hand, The high-density waste paper is coarsely crushed by the coarse portion 12X in the office.  also, In the first device 100A, As shown by the arrow in Figure 7, The settings are supplied by each office X1 X2 The supply port 20K of the coarse crushed material 12X in the X3. The supply port 20K is a portion for supplying coarse debris to the defibrating unit 20. which is, Office X1 X2 The user of X3 transports the coarse debris in the office to the backcourt and puts it into the supply port 20K. And the first device 100A is activated, Thereby, defibrated fibers are obtained. then, By bringing the obtained defibrated fiber into each office X1 X2 X3, And invested in the configuration of each office X1 X2 The second device 100B of X3, The second device 100B is operated to manufacture the sheet S.  in this way, Can be in each office X1 X2 Sheet S is made in X3, One side of each office X1 X2 Users of X3 share coarse crush, The defibrating device is the first device 100A. therefore, The number of the first device 100A can be reduced while the effect of the configuration pattern A is obtained.  As mentioned above, For configuration in each office X1 X2 In the second device 100B of X3, The sheet manufacturing amount is measured by the control device 101B (Fig. 2). The amount of sheet production can be confirmed by the user or the like, And compare each office X1 X2 The amount of sheet material produced by X3. This comparison result is effective information for improving the arrangement of the first device 100A and the second device 100B. E.g, It is easy to take the configuration in which the second device 100B is stopped in an office where the sheet manufacturing amount is small, Or countermeasures to move the second device 100B to another office. also, It is easy to take measures to move the first device 100A to a position close to an office where the sheet manufacturing amount is large. also, When configuring a printing device in each office, Can control the amount of printing in each office, However, measures are taken to move the first device 100A to a position close to an office having a large amount of printing.  (Fifth Embodiment) Fig. 8 is a view showing a schematic configuration of a sheet manufacturing system 1 according to a fifth embodiment.  The fifth embodiment can be used in a plurality of offices X1. X2 The sheet S is coarsely crushed and defibrated in X3. the following, Points different from the first embodiment will be described.  Coarse, The defibrating device, that is, the first device 100A is disposed in the office X1. X2 X3 each. also, The second apparatus 100B, which is a sheet manufacturing apparatus, is disposed in the back field. which is, The fifth embodiment is an arrangement corresponding to the above-described pattern C.  At office X1 X2 Each of X3 is provided with a recycling box 11 for recycling waste paper in each office. also, Figure 8 shows the PC used by the users of each office X1 ~ X3 (marked 1X in Figure 8, 2X, 3X and display), And the printing device for printing to the user in each office X1 to X3 (marked 1Y in Fig. 8, 2Y, 3Y and show). Each PC1X, 2X, 3X and printing device 1Y, 2Y, 3Y can be communicatively connected via a communication network NW. The communication network NW is a wired or wireless communication network. A well-known communication network can be widely applied.  As shown in Figure 8, Due to office X1 X2 The X3 configuration has coarse, The defibrating device is the first device 100A, Therefore, the user can crush and defoam the waste paper such as confidential paper in the office. It is good for preventing leakage of confidentiality. also, Due to office X1 X2 The X3 is equipped with a recycling box 11, Therefore, the waste paper recovered to the recovery box 11 can also be coarsely crushed and defibrated in the office by the first device 100A.  also, As shown by the arrow in Figure 8, The cassette 200 discharged from the first device 100A is carried to the back field. And installed in the second device 100B configured in the rear place, It is used for the manufacture of sheet S. then, The manufactured sheet S is transported from the back yard to each office X1. X2 X3, And installed in each office X1 X2 X3 printing device 1Y, 2Y, 3Y. With this, According to PC1X from each office X1 ~ X3, 2X, The 3X printed material is printed on the sheet S.  in this way, Can be in each office X1 X2 In X3, the waste paper is coarsely crushed and defibrated. One side of each office X1 X2 The user of X3 shares the second device 100B which is a sheet manufacturing apparatus. therefore, The number of the second devices 100B can be reduced while the effect of the configuration pattern C is obtained.  As mentioned above, For configuration in each office X1 X2 In the first device 100A of X3, The amount of waste paper processed indicating the amount of coarse crushing and defibration is measured by the control device 101A. Confirming the amount of sheet production by the user or the like, And compare each office X1 X2 The amount of waste paper processed by X3. The comparison result is effective information for improving the configuration of the first device 100A. E.g, It is easy to adopt an office that has a small amount of waste paper processing to stop the configuration of the first device 100A, Or a countermeasure to move the first device 100A to another office. also, It is also possible to move the second device 100B to a position close to the office of the office having a large amount of waste paper processing.  (sixth embodiment) The sixth embodiment differs from the first embodiment in that the second device 100B, which is a sheet manufacturing apparatus, has a printing unit 1Z that prints the sheet S.  Fig. 9 is a block diagram showing the configuration of a control system including the second device 100B of the sixth embodiment. The second device 100B is provided with a sheet supply mechanism (not shown) that supplies the sheet S discharged to the discharge unit 96 to the printing unit 1Z. Further, the manufactured sheet S can be printed by the printing unit 1Z.  also, The second device 100B is set to be used to communicate with an external device via the communication network NW (in the example of FIG. 9, PC1X, 2X, 3X, etc. communication unit 105B for communication. The control device 101B of the second device 100B is connected to the PC1X from an external device by the communication unit 105B. 2X, 3X and other receiving printed materials. then, When receiving printed materials, The control device 101B performs print control for printing a print image corresponding to the print material on the sheet S by the printing unit 1Z. According to this configuration, Compared to the case of configuring a separate printing device, The efficiency of setting up the machine is improved.  Here, When the control device 101B receives the printed material as a printing start instruction, The sheet S can be manufactured by printing a start instruction as a trigger.  Fig. 10 is a flow chart showing an example of the operation when the sheet S is manufactured by the printing start instruction.  When the control device 101B receives the print material (corresponding to the print start instruction) (step S1D: Yes (YES)), Based on the amount of printing specified based on the printed materials, It is determined whether or not it is necessary to manufacture the sheet S (step S2D).  Whether or not it is necessary to manufacture the sheet S is determined based on the remaining amount of the sheet S remaining in the discharge portion 96. E.g, The control device 101B is configured to detect the remaining amount of the sheet S remaining in the discharge portion 96 by the remaining amount sensor 104B. And when the remaining amount of the sheet S is more than the printing amount, It is determined that it is not necessary to manufacture the sheet S (step S2D: No (NO)). In this case, The control device 101B starts the control of feeding the sheet S remaining in the discharge unit 96 to the printing unit 1Z (step S3D). then, The control device 101B determines whether or not the paper feed is ended (step S4D). When the control device 101B supplies the sheet S of the printing target to the printing unit 1Z, It is determined that the paper feed is ended (step S4D: Yes), And the paper feeding is stopped (step S5D).  In step S2D, When the control device 101B remains in the case where the sheet S of the discharge unit 96 does not reach the printing amount (when the printing amount is not satisfied), It is determined that it is necessary to manufacture the sheet S (step S2D: Yes). another, The remaining amount of the sheet S is more than the printing amount, However, if it is still less than the preset set remaining amount, It can also be determined that it is necessary to manufacture the sheet S. In the case where it is determined that the sheet S needs to be manufactured (step S2D: Yes), The control device 101B proceeds to the process of step S6D, And taking the sheet S which is insufficient, as the sheet to be manufactured, Specify the target manufacturing quantity to ensure the number of sheets is insufficient. The target manufacturing quantity can be the same as the insufficient number of sheets. It can also be set to more than the number of sheets. then, The control device 101B starts the manufacture of the sheet S to be manufactured (step S7D).  The control device 101B determines whether or not the manufacture of the sheet S is ended (step S8D), At the end of the manufacturing situation, The operation of each unit of the second device 100B is stopped (step S9D). The case where the manufacturing is completed is a case where the manufacturing amount of the sheet S reaches the target manufacturing amount.  then, The control device 101B starts the control of feeding the manufactured sheet S to the printing unit 1Z via the discharge unit 96 (step S10D). also, The control device 101B determines whether or not the paper feed of the sheet S is ended (step S11D), And at the end of the paper feeding situation, The control of paper feeding is stopped (step S12D). In the case where the sheet feeding is ended, the sheet S corresponding to the number of sheets of the printing amount is supplied to the printing unit 1Z. With the above, When the sheet S of the printing object is insufficient, Can produce insufficient sheet S, And the paper is fed to the printing unit 1Z.  in this way, Since the sheet S can be manufactured by triggering the printing start instruction, Therefore, the sheet S can be manufactured as needed according to the printing start instruction. And, Since it is determined based on the remaining amount of the sheet S whether or not the sheet S is manufactured, Therefore, the sheet S can be automatically replenished appropriately according to the remaining amount of the sheet S. also, Since the second apparatus 100B which is the sheet manufacturing apparatus is integrated with the printing unit 1Z, Therefore, the manufacture of the sheet S can be smoothly performed, And printing of the manufactured sheet S. another, Sheet S can be manufactured on one side, The printing of the sheet S is carried out in parallel.  In the sixth embodiment, The second device 100B can be configured to electrostatically manufacture the sheet S.  Figure 11 is a view showing the main part when the sheet S is electrostatically produced (hereinafter, The expression is a schematic diagram of the sheet manufacturing unit 75).  The sheet manufacturing unit 75 electrostatically transfers the fiber-containing material that is the raw material of the sheet S to the conveyance belt 401 (transferable body). The sheet S is produced by performing treatment after adjusting the surface properties.  The sheet manufacturing unit 75 has: Supply unit 410, It supplies fiber-containing material; Carrier 420 (second carrier), It carries the supplied fibrous material; Carrying belt 401, a fiber-containing material carried by the electrostatic transfer; And post-processing unit 430, It is post-processed.  In the sheet manufacturing unit 75, The fiber-containing material is electrostatically transferred from the carrier 420 to the transfer target (transport belt 401). With this, It is possible to prevent unevenness in the adhesion amount of the fiber-containing material adhering to the transfer target (transport belt 401). which is, The fiber-containing material is appropriately attached to the transfer target (transport belt 401). the result, The sheet S obtained from the fiber-containing material having a uniform thickness can be stably produced.  The fiber-containing material that becomes the raw material consists of cellulose fibers, And a composite of a hydrophobic material covering at least a portion of the cellulose fibers, The sheet S is formed by pressurization and heating by the post-processing unit 430.  Cellulose fiber can be derived from cellulose products such as waste paper. Can also be derived from the original pulp, Therefore, fibers containing cellulose can be widely used. E.g, Cellulose fibers obtained by defibrating the waste paper can be used.  The hydrophobic material causes the cellulose fibers to adhere to each other to form the sheet S. Furthermore, The hydrophobic material is coated with cellulose fibers, And the charging characteristics of the composite are stabilized. With this, The sheet S can be preferably formed by electrostatic coating. For hydrophobic materials, For example, a thermoplastic resin can be used, Or a curable resin or the like.  also, The hydrophobic material may also contain a charge control agent (charge control agent) for obtaining a desired charge characteristic, Or a coloring agent for adjusting the color of the sheet S.  As shown in Figure 11, The supply unit 410 stores the storage unit 412, Mixer 413 (Agitator), Roller 414, The first carrier 415, The squeegee 416 is housed in the outer casing portion 411.  The storage portion 412 stores a fiber-containing material containing cellulose fibers and a thermoplastic resin. The agitator 413 agitates the fiber-containing material in the storage portion 412. The fiber-containing material is charged by friction during agitation. The fiber-containing material is supplied to the first carrier 415 by the rotation of the roller 414. There is a potential difference between the first carrier 415 and the roller 414. And the static electricity adheres to the fiber-containing material. The squeegee 416 adjusts (thickness) the thickness (adhesion amount) of the fiber-containing material adhering to the first carrier 415 to a specific thickness. And the fiber-containing material is charged by friction.  There is a potential difference between the carrier 420 and the first carrier 415. And the static electricity adheres to the fiber-containing material. The carrier 420 is a rotating roller member. The fiber-containing material carried on the carrier 420 is transferred to the conveyor belt 401.  Around the carrier 420, A charging portion 422 for charging the outer circumferential surface 421 of the carrier 420 is provided, And an exposure unit 423 that adjusts the potential of the outer peripheral surface 421. Furthermore, The fiber-containing material is transferred to the transfer portion 424 of the conveyance belt 401 by an electrostatic force generated by a potential difference from the carrier 420 around the carrier 420.  also, The transfer unit 424 pressurizes the fiber-containing material transferred to the conveyor belt 401 between the carrier 420 and the carrier 420. The thickness of the fiber-containing material is adjusted to a uniform thickness. The conveyor belt 401 is composed of a belt of a ring shape. And it is conveyed by the multiple roller 402. The conveying belt 401 is preferably made of a medium that transfers the fiber-containing material, A resin having a high electrical resistance (volume resistivity: 107 to 1011 Ω·cm). The constituent material is not particularly limited. For example, it can be used for mixing a fluorine-based resin into carbon black. With this, The powder of the fiber-containing material is transferred to the conveyor belt 401 by a potential difference, Further, it is easy to hold the static electricity on the conveyor belt 401.  The post-processing unit 430 is provided with: Flattening processing unit 431, It smoothes the surface of the fiber-containing material transferred to the conveyor belt 401; Pressurization processing unit 432, Pressurized fiber-containing material; The semi-curing processing unit 433, It semi-cures the surface of the fibrous material; And curing unit 434, It solidifies the layered fibrous material. The flattening processing unit 431 is a flattening roller 435 having at least a metal surface on the outer peripheral surface thereof. Smoothing the surface of the fiber-containing material by the flattening roller 435, The fiber-containing material is neutralized via a ground line 436.  The pressurizing treatment portion 432 bonds the fiber-containing materials to each other by the pressurization of the pressure roller 437. And the density is uniformized. The semi-curing treatment portion 433 has a chamber 438 made of a heat insulating material, And a heater 439 disposed in the chamber 438, The surface of the fiber-containing material is semi-cured by heating by the heater 439.  The curing portion 434 has a curing roller 440, And a heater 441 disposed in the curing roller 440, The curing roller 440 is heated by energizing the heater 441, And heating the fiber-containing material by the curing roller 440, The fibrous material is pressurized in the direction in which the layer thickness is reduced. With this, The thermoplastic resin in the fiber-containing material is melted, And after the molten thermoplastic resin passes through the curing roller 440, For example, it is naturally cooled to adhere and cure. in this way, Producing a fiber-containing material that is suitably cured, That is, the sheet S.  A blower fan (not shown) that facilitates peeling of the sheet S from the conveyance belt 401 is provided downstream of the post-processing unit 430, And a cutting unit 90 (not shown) or the like.  The sheet manufacturing portion 75 does not require the formation of a mesh or the like. Therefore, it is easy to shorten the manufacturing time of the sheet S. therefore, When the sheet S is manufactured by the control or the like shown in FIG. 10, The sheet S can be manufactured in a short time.  another, The above embodiments are only specific embodiments of the invention described in the scope of the claims. Not limiting the inventor, It is also not intended that all of the configurations described in the respective embodiments are essential components of the present invention. also, The invention is not limited to the constituents of the respective embodiments. It can be implemented in various aspects without departing from the spirit of the invention.  E.g, In various embodiments, The case where the present invention is applied to the dry sheet manufacturing system 1 is explained. But it is not limited to this. For example, the present invention can be applied to put a material containing fibers into water, A sheet manufacturing system for producing a sheet by a wet type (for example, a wet paper making method) which is subjected to fiber dissociation and reconstituted.  In the case of wet, E.g, The coarse crushed material is put into a pulverizer to wet the fiber, And do not compress the paper, It is stored (filled) in the dry state to the cassette 200. also, Can replace the method of being stored in the cassette 200, Since the defibrated fiber contains moisture, Therefore, the defibrating fiber is subjected to extrusion treatment such that the defibrated fiber has shape retainability. It is also possible to easily form the defibrated fiber in a movable form. In this case, It is easy to treat the defibrated fiber into a state of shape retention.  also, The sheet manufacturing system 1 may be configured to produce a plate shape composed of a hard sheet or a laminated sheet. Or the manufacture of the mesh, It is not limited to the sheet S. also, The properties of the sheet S are not particularly limited. It can be used as a recording paper for writing or printing (for example, PPC (Plain Paper Copy: Plain paper photocopying) paper) paper used, Can also be wallpaper, wrapper, Colored paper, Painting paper, Kent Paper, etc. also, When the sheet S is a non-woven fabric, In addition to the general non-woven fabric, Can also be used as a fiberboard, toilet paper, Kitchen paper, Cleaning sheet, Filter, Liquid absorbing material, Sound absorbing material, Buffer material, Gaskets, etc.  also, The present invention is not limited to the case of being applied to the sheet manufacturing system 1, It is also possible to only apply the defibrating device having the defibrating unit 20, The present invention is applied to a sheet manufacturing apparatus for producing a sheet S by defibrating fibers. In this case, The defibrating device is configured as a device having at least the defibrating unit 20 and the fiber processing unit 40, E.g, Using the first device 100A, The composition of 110A. According to this configuration, Easy to handle defibrated fibers, The defibrating device can be easily installed in an office or the like. also, The sheet manufacturing apparatus is configured to have a supply port 46 to which a disintegrated fiber of a movable form is supplied, And using the device for producing the sheet S by the dismantled fiber of the movable form supplied to the supply port 46, E.g, The configuration of the second device 100B is employed. According to this configuration, Sheets can be made from dismantled fibers in a formable form, Moreover, it is easy to install a sheet manufacturing apparatus in an office or the like.  also, The use side device using the manufactured sheet S is not limited to the printing device 1Y, 2Y, 3Y and Printing Department 1Z, A device capable of utilizing the sheet S can be widely applied. also, At least a part of the functional blocks shown in each figure can be implemented by hardware. It can also be realized by the cooperation of hardware and software. It is not limited to the configuration of a separate hardware resource. also, The executed program can be memorized in the non-volatile memory, Or other memory device (omitted from illustration). It can also be configured to receive a program that is stored in an external device.

1‧‧‧Sheet Manufacturing System

1‧‧‧Bowl

2‧‧‧ tube

3‧‧‧ tube

4‧‧‧ tube

7‧‧‧ tube

8‧‧‧ tube

9‧‧‧ tube

10‧‧‧Supply Department

11‧‧‧Recycling box

12‧‧‧Grade

12X‧‧‧Grunting Department

12K‧‧‧ supply port

14‧‧‧

20‧‧‧Defibration Department

22‧‧‧Import

23‧‧‧Import

24‧‧‧Export

20K‧‧‧ supply port

30‧‧‧Sorting Department

31‧‧‧Turning Department

32‧‧‧Import

33‧‧‧ Shell Department

34‧‧‧Export

35‧‧‧1st mesh formation

36‧‧‧Net belt

37‧‧‧ Roll

38‧‧‧Attraction

39‧‧‧Rotating body

40‧‧‧Fiber Processing Department (Processing Department)

40A‧‧‧Gravity Processing Department (Processing Department)

42‧‧‧Exporting Department

42A‧‧‧Exporting Department

45‧‧‧Fiber Supply Department

45A‧‧‧Gravel Supply Department

46‧‧‧ supply port

46A‧‧‧ supply port

50‧‧‧Additive Mixing Department

52‧‧‧Additive Supply Department

56‧‧‧Mixed air blower

60‧‧‧Stacking Department

61‧‧‧Turning Department

62‧‧‧Import

63‧‧‧Shell Department

70‧‧‧Sheet forming department

71‧‧‧2nd mesh formation

72‧‧‧Net belt

74‧‧‧roll

75‧‧‧Sheet Manufacturing Department

76‧‧‧sucking mechanism

78‧‧‧Humidification Department

79‧‧‧Transportation Department

82‧‧‧ Pressurization

84‧‧‧heating department

85‧‧‧pressure roller

86‧‧‧heating roller

90‧‧‧cutting department

92‧‧‧1st cut-off

94‧‧‧2nd cut-off

96‧‧‧Exporting Department

100A‧‧‧1st device

100B‧‧‧Second device (sheet manufacturing department)

101A‧‧‧Control device

101B‧‧‧Control device

102A‧‧‧Operation Department

102B‧‧‧Operation Department

103A‧‧‧Display Department

103B‧‧‧Display Department

104A‧‧‧Remaining sensor

104B‧‧‧Remaining sensor

105B‧‧‧Communication Department

110A‧‧‧1st device

110C‧‧‧3rd device

111A‧‧‧Control device

111C‧‧‧Control device

112A‧‧‧Operation Department

112C‧‧‧Operation Department

113A‧‧‧Display Department

113C‧‧‧Display Department

114A‧‧‧Remaining sensor

114C‧‧‧Remaining sensor

120A‧‧‧4th device

121A‧‧‧Control device

122A‧‧‧Operation Department

123A‧‧‧Display Department

124A‧‧‧Remaining sensor

200‧‧‧Carmen

210‧‧‧Carmen

401‧‧‧Transportation belt

402‧‧‧ Roll

410‧‧‧Supply Department

411‧‧‧ Shell Department

412‧‧‧ Storage Department

413‧‧‧Mixer

414‧‧‧roll

415‧‧‧1st carrier

416‧‧‧Scraper

420‧‧‧ Carrying body

421‧‧‧ outer perimeter

422‧‧‧Power Department

423‧‧‧Exposure Department

424‧‧‧Transfer Department

430‧‧‧Reprocessing Department

431‧‧‧ Flattening Department

432‧‧‧ Pressurization Department

433‧‧‧ Semi-curing treatment department

434‧‧‧Cure Department

435‧‧‧Pushing roller

436‧‧‧ Grounding wire

437‧‧‧Pressure roller

438‧‧‧室

439‧‧‧heater

440‧‧‧curing roller

441‧‧‧heater

1X‧‧‧PC

2X‧‧‧PC

3X‧‧‧PC

1Y‧‧‧Printing device

2Y‧‧‧Printing device

3Y‧‧‧Printing device

1Z‧‧‧Printing Department

F‧‧‧Transfer direction

NW‧‧‧Communication Network

S‧‧‧Sheet

S1D～S12D‧‧‧ steps

V1‧‧‧ speed

V2‧‧‧ speed

W1‧‧‧1st mesh

W2‧‧‧2nd mesh

X1‧‧ office

X2‧‧ office

X3‧‧ office

Fig. 1 is a view showing the configuration of a sheet manufacturing system according to a first embodiment. Figure 2 is a block diagram showing the construction of a control system including a sheet manufacturing system. Fig. 3 is a view showing an example of a plurality of configuration patterns. Fig. 4 is a block diagram showing the configuration of a control system including a sheet manufacturing system according to a second embodiment. Fig. 5 is a view showing an example of a plurality of configuration patterns. Fig. 6 is a block diagram showing the configuration of a control system including a sheet manufacturing system according to a third embodiment. Fig. 7 is a view showing a schematic configuration of a sheet manufacturing system according to a fourth embodiment. Fig. 8 is a view showing a schematic configuration of a sheet manufacturing system according to a fifth embodiment. Fig. 9 is a block diagram showing the configuration of a control system including a second device of the sixth embodiment. Fig. 10 is a flow chart showing an example of the operation when a sheet is manufactured. Fig. 11 is a view for explaining a modification of the sixth embodiment.

Claims (15)

A sheet manufacturing system comprising: a defibrating unit that defibrates a raw material containing fibers; a sheet manufacturing unit that produces a sheet; and a processing unit that sets the defibrated fiber from which the defibrating unit is defibrated The sheet forming unit is configured to produce the sheet by using the disintegrated fiber of the movable form. The sheet manufacturing system according to claim 1, wherein the processing unit stores the defibrated fibers defibrated by the defibrating unit in a container. The sheet manufacturing system of claim 1, wherein the processing unit processes the defibrated fibers defibrated by the defibrating unit into a shape retaining state. The sheet manufacturing system according to claim 2 or 3, wherein the processing unit processes the defibrated fiber into any of a plate shape, a rectangular parallelepiped shape, and a spherical shape. The sheet manufacturing system of claim 2, wherein the processing unit vacuum-packs the defibrated fiber. The sheet manufacturing system according to any one of claims 1 to 5, wherein the disintegrating fiber of the above-described movable form comprises a binder. The sheet manufacturing system according to any one of claims 1 to 6, comprising: a first device having the defibrating unit; and a second device having the sheet manufacturing unit. The sheet manufacturing system of claim 7, wherein the first device and the second device are independently operable. The sheet manufacturing system according to any one of claims 1 to 8, wherein the sheet manufacturing unit has a printing unit that prints on the sheet. The sheet manufacturing system of claim 9, wherein the sheet manufacturing unit manufactures the sheet by triggering a printing start instruction. A sheet manufacturing system according to claim 7 or 8, comprising a third device having a coarsely crushed portion of the raw material of the defibrated object obtained by coarsely pulverizing the paper. The sheet manufacturing system according to any one of claims 1 to 11, wherein the defibrating unit is dry. The sheet manufacturing system according to any one of claims 1 to 11, wherein the defibrating portion is wet. A defibrating device comprising: a defibrating unit that defibrates a raw material containing fibers; and a processing unit that converts the defibrated fibers from which the defibrating unit is defibrated into a movable form. A sheet manufacturing apparatus comprising a supply port for supplying a defibrated fiber in a movable form, and a sheet manufacturing unit for producing a sheet by the defibrated fiber supplied to the supply port.