TW201832887A - Sheet production device, and sheet production system - Google Patents

Abstract

The present invention is capable of rapidly producing sheets and discharging the sheets in accordance with the use side of said sheets. This sheet production device 100 is equipped with a sheet production unit 101 for producing sheets S, and a sheet delivery unit 103M for delivering the sheets S produced by the sheet production unit 101 to a printing device which is the use side of said sheets S. In addition, a control device of the sheet production device 100 causes the sheet production unit 101 to produce sheets S in accordance with printing needs, and causes the sheet delivery unit 103M to supply the sheets S to the use side.

Description

Sheet manufacturing apparatus and sheet manufacturing system

The present invention relates to a sheet manufacturing apparatus and a sheet manufacturing system.

The present invention proposes a sheet manufacturing apparatus which manufactures a sheet and is stacked and housed in a discharge unit (see Patent Document 1). In such a sheet manufacturing apparatus, the sheet stored in the discharge portion is considered to be used as printing paper or the like. Further, a device for feeding a sheet stored in a storage portion such as a discharge portion is known (for example, see Patent Document 2). Patent Document 2 discloses a reproduction processing mechanism for erasing an image formed on a sheet, and feeding the regenerated sheet from a storage portion (hereinafter referred to as a storage portion) to the image forming portion. An image forming system for images. [PRIOR ART DOCUMENT] [Patent Document 1] Japanese Patent Laid-Open Publication No. Hei. No. Hei. No. Hei. No. Hei.

[Problems to be Solved by the Invention] The device described in Patent Document 2 is configured such that the reprocessed sheet is stacked in the storage portion and discharged from the upper portion to the image forming portion. In Patent Document 2, when a sheet is supplied to the accommodating portion and the sheet is discharged from the accommodating portion at the same time, a conveyance error such as clogging or double feed may occur, or wrinkles may occur in the sheet. The rupture. In the case where the accommodating portion described in Patent Document 2 is applied to the sheet manufacturing apparatus, if the sheet to be produced is supplied to the accommodating portion and the sheet is discharged from the accommodating portion, a conveyance error occurs. The manufacture of materials and other factors. Therefore, if the sheet in the accommodating portion in the sheet discharged from the accommodating portion is insufficient, the printing is finished in the middle and the waiting time for printing is prolonged. Therefore, an object of the present invention is to rapidly manufacture a sheet in conjunction with a use side and to discharge the sheet. [Means for Solving the Problem] In order to achieve the above-described problem, the sheet manufacturing apparatus of the present invention includes a sheet manufacturing unit that manufactures a sheet, and a sheet feeding unit that manufactures a sheet produced by the sheet manufacturing unit. The sheet is fed to the use side, and the control unit causes the sheet manufacturing unit to manufacture the sheet according to a request from the use side, and the sheet feeding unit supplies the sheet to the use side. According to the present invention, the sheet can be quickly produced in combination with the use side and the sheet can be discharged. Further, in the present invention, the control unit acquires the use target information related to the sheet to be used, specifies the sheet to be used based on the use target information, and causes the sheet manufacturing unit to manufacture the sheet to be used. . According to the present invention, the sheet of the object to be used can be easily specified, and the sheet to be used can be preferentially produced. Further, in the present invention, the control unit acquires the use target information related to the sheet to be used, specifies the usage amount based on the use target information, and controls the amount of manufacture of the sheet manufacturing unit based on the usage amount. According to the present invention, the amount of use can be easily specified, and the sheet of the amount corresponding to the amount used can be preferentially produced. Moreover, the sheet manufacturing system of the present invention includes: a sheet manufacturing unit that manufactures a sheet; a supply unit that feeds the sheet produced by the sheet manufacturing unit; and a printing unit that feeds the sheet to the supply unit And the control unit causes the sheet manufacturing unit to manufacture a sheet to be printed, and supplies the sheet to the printing unit by the supply unit. According to the present invention, the sheet can be quickly manufactured in accordance with the printing request, and the sheet can be discharged. For example, by applying a configuration capable of producing a sheet in a short time to the sheet manufacturing portion, the sheet can be produced as needed and supplied to the printing portion. Further, in the present invention, the control unit acquires the printing target information relating to the sheet to be printed, specifies the sheet to be printed based on the printing target information, and causes the sheet manufacturing unit to manufacture the sheet to be printed. . According to the present invention, the sheet to be printed can be easily specified, and the sheet to be used can be preferentially produced. Further, in the present invention, the control unit acquires the printing target information related to the sheet to be printed, specifies the printing amount based on the printing target information, and controls the manufacturing amount of the sheet manufacturing unit based on the printing amount. According to the present invention, the amount of printing can be easily specified, and the sheet of the amount corresponding to the amount of printing can be preferentially produced. Further, in the invention, the information to be printed is information included in the printed material supplied to the printing unit. According to the present invention, the sheet or the amount of printing of the printing target can be correctly specified.

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, all of the configurations described below are not essential components of the present invention. (First Embodiment) Fig. 1 is a view showing a sheet manufacturing system 1 according to a first embodiment. The sheet manufacturing system 1 includes a sheet manufacturing apparatus 100 that manufactures a sheet, and a printing apparatus 105 that prints (records) an image on a sheet manufactured by the sheet manufacturing apparatus 100. The sheet manufacturing apparatus 100 is preferably made of a waste paper (sheet) which has been used as a raw material as a raw material, which is fibrillated by dry defibration, and then pressurized, heated, and cut to produce new paper (hereinafter referred to as Sheet) device. 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 (basis weight) of the paper, the thickness, the shape, and the coloring agent (color material) contained in the paper, it can be molded to produce at least one of a basis weight, a size, and a color depending on the application. Kind of paper. The sheet manufacturing apparatus 100 includes a sheet manufacturing unit 101 that manufactures a sheet which is a sheet of paper, and a storage unit 102 that stores the manufactured sheet. The accommodating portion 102 is an automatic paper feeder (also referred to as a paper stacker or a tray) that can store a plurality of sheets and feed the printing device 105. The printing device 105 receives the printed material from an external device (not shown) such as a personal computer, and prints the printed matter to the sheet supplied from the storage unit 102 based on the printed material. The printing device 105 has a control unit 105A that controls each unit of the printing device 105. The control unit 105A can communicate with the sheet manufacturing apparatus 100 by wire or wirelessly. Further, in the printing apparatus 105, a manual insertion paper feeder (hereinafter referred to as a manual insertion storage unit 104) for manually inserting paper feed to the printing apparatus 105 is connected. The manual insertion accommodating portion 104 can feed a sheet of paper of a different size from the accommodating portion 102 or a sheet of the same size. The printing device 105 is, for example, an inkjet printer. The printing device 105 can also be an electrophotographic printing device such as a thermal printer or a laser printer. Further, the manual insertion and storage unit 104 is an option that is appropriately added and can be omitted. FIG. 2 is a schematic view showing the configuration of the sheet manufacturing unit 101 and the storage unit 102. The sheet manufacturing unit 101 includes a supply unit 10, a coarse crushing unit 12, a defibrating unit 20, a sorting unit 40, a first mesh forming unit 45, a rotating body 49, a mixing unit 50, a stacking unit 60, and a second mesh. The object forming unit 70, the conveying unit 79, the sheet forming unit 80, and the cutting unit 90. Further, the sheet manufacturing apparatus 100 includes humidifying units 202, 204, 206, 208, 210, and 212 for the purpose of humidifying the raw material and/or humidifying the space in which the raw material is moved. The specific configuration of the humidifying units 202, 204, 206, 208, 210, and 212 is arbitrary, and examples thereof include a steam type, a vaporization type, a warm air vaporization type, and an ultrasonic type. In the present embodiment, the humidifying units 202, 204, 206, and 208 are constituted by a gasification type or a warm air-vaporizing type humidifier. In other words, the humidifying units 202, 204, 206, and 208 have a filter (not shown) that partially wets water, and the humidified air after the humidity is increased by passing the air through the filter. Further, the humidifying units 202, 204, 206, and 208 may be provided with a heater (not shown) that effectively increases the humidity of the humidified air. Further, in the present embodiment, the humidifying unit 210 and the humidifying unit 212 are constituted by an ultrasonic humidifier. In other words, the humidifying units 210 and 212 have a vibrating portion (not shown) that atomizes water, and supplies the mist generated by the vibrating portion. The supply unit 10 supplies the raw material to the coarse crushing portion 12. The raw material for producing the sheet in the sheet manufacturing apparatus 100 may be any one containing fibers, and examples thereof include paper, pulp, pulp sheets, cloths containing nonwoven fabrics, and woven fabrics. In the present embodiment, the sheet manufacturing apparatus 100 is configured by using waste paper as a raw material. The coarse crushing portion 12 coarsely crushes the raw material supplied from the supply portion 10 by the coarse crushing blade 14 into a coarse chip (coarse material). 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 includes a pair of rough cutting edges 14 which are sandwiched with 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 coarse crushing portion 12 has a cartridge (also referred to as a hopper) 9 that receives coarse fragments that are coarsely crushed by the coarse crushing blade 14. The cartridge 9 has a tapered shape in which the width gradually narrows in the direction in which the coarse debris flows (the direction of travel), and functions as a guide portion that receives and collects the diffused coarse fragments below the coarse crushing blade 14. A pipe 2 that communicates with the defibrating unit 20 is connected to the cylinder 9, and the pipe 2 forms a conveying path for conveying the raw material (coarse chips) coarsely crushed by the coarse cutting blade 14 to the defibrating unit 20. The coarse chips are collected by the barrel 9 and transferred (transferred) through the tube 2 to the defibrating unit 20. Thereby, the tube 2 functions as a discharge portion that discharges the coarse fragments collected by the cartridge 9. In the vicinity of the cylinder 9 or the cylinder 9 which the coarse crushing portion 12 has, the humidifying portion 202 supplies the humidified air. Thereby, it is possible to suppress the phenomenon that the coarse crushed material coarsely crushed by the coarse crushing blade 14 is adsorbed to the inner surface of the cylinder 9 or the tube 2 due to static electricity. Further, since the coarsely crushed coarse crushed material is transferred to the defibrating unit 20 together with the humidified (high humidity) air, the effect of suppressing the adhesion of the defibrated material inside the defibrating unit 20 can be expected. Further, the humidifying unit 202 may be configured to supply humidified air to the rough cutting blade 14 to de-energize the raw material supplied from the supply unit 10. The defibrating unit 20 defibrates the coarsely divided material from the coarsely divided portion 12. More specifically, the defibrating unit 20 defibrates the coarse chips which are coarsely crushed by the coarse crushing portion 12 as a raw material to produce a defibrated material. Here, "defibration" means that a raw material (defibrated material) obtained by laminating a plurality of fibers is untwisted into one fiber. The defibrating unit 20 also has a function of separating the resin particles or 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 unzipped fibrillated fibers, the so-called "defibrillation" also includes a resin that separates the fibers when the fibers are unwound (a resin used to bond a plurality of fibers to each other), ink, toner, and toner. A coloring agent, or an additive such as a barrier agent or a paper strength enhancer. The shape of the untwisted defibrated material is a string shape or a ribbon shape. The unzipped defibrated material may also exist in a state of being entangled with other untwisted defibrated materials (independent state), and may be entangled with other unraveled defibrated materials into a block-like state (formation of so-called formation) The state of the "clump" 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, not in 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 lining (not shown) located on the outer circumference of the rotor. The coarse chips coarsely shredded by the coarse crushing portion 12 are interposed between the rotor of the defibrating portion 20 and the lining 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 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 40 via the tube 3. In this way, the defibrated material generated in the defibrating unit 20 is transported from the defibrating unit 20 to the sorting unit 40 by the air flow generated by the defibrating unit 20. In the present embodiment, the sheet manufacturing apparatus 100 includes the defibrating unit blower 26 which is an airflow generating device, and the defoamed material is conveyed to the sorting unit 40 by the airflow generated by the defibrating unit blower 26. The defibrating unit blower 26 is attached to the tube 3, and simultaneously desorbs the defibrated material and air from the defibrating unit 20, and supplies the air to the sorting unit 40. The sorting unit 40 has an introduction port 42 through which the defibrated material defibrated by the defibrating unit 20 flows into the tube 3 together with the air flow. The sorting unit 40 sorts the defibrated materials introduced into the introduction port 42 in accordance with the length of the fibers. Specifically, the sorting unit 40 sets the defibrated material having a predetermined size or less in the defibrated fiber defibrated by the defibrating unit 20 as the first sorting material, and the defibrated material larger than the first sorting material as the first Sort by 2 sorts. The first sorting includes fibers, or particles, and the like, and the second sorting includes, for example, larger fibers, undecomposed sheets (crude fragments not sufficiently defibrated), defibrated fibers coagulated, or entangled agglomerates Wait. In the present embodiment, the sorting unit 40 includes a drum portion 41 (screen portion) and an outer casing portion 43 (cover portion) that houses the drum portion 41. The drum portion 41 is a cylindrical sieve that is rotationally driven by a motor. The drum portion 41 has a mesh (filter, mesh) and functions as a sieve. With this mesh, the drum portion 41 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 41, for example, a metal mesh, an expanded metal plate for stretching a metal plate having a slit, and a punched metal plate having a press machine equal to a metal plate to form a hole can be used. The defibrated material introduced into the introduction port 42 is conveyed to the inside of the drum portion 41 together with the air current, and the first sorting object is dropped from the mesh of the rotating cylinder portion 41 to the lower side by the rotation of the drum portion 41. The second sorting which cannot pass through the mesh of the drum portion 41 flows through the airflow flowing into the drum portion 41 from the introduction port 42, and is guided to the discharge port 44 and sent to the tube 8. The tube 8 connects the inside of the drum portion 41 and the tube 2, and the second sorting material flowing through the tube 8 flows along with the coarse chips shredded by the coarse crushing portion 12 to the tube 2, and is guided to the introduction of the defibrating portion 20. Port 22. Thereby, the second sorting object is returned to the defibrating unit 20 to be defibrated. Further, the first sorting object sorted by the drum portion 41 is dispersed into the air through the mesh of the drum portion 41, and is directed to the mesh belt of the first web forming portion 45 located below the drum portion 41. 46 fell. The first mesh forming portion 45 (separating portion) includes a mesh belt 46 (separating belt), a roller shaft 47, and a suction portion 48 (suction mechanism). The mesh belt 46 is a ring-shaped belt that is suspended from the three roller shafts 47 and is conveyed in the direction indicated by the arrow in the figure by the rotation of the roller shaft 47. The surface of the mesh belt 46 is formed by a mesh of openings of a particular size. The particles passing through the size of the mesh drop from the first sort of the sorting portion 40 are dropped below the mesh belt 46, and the fibers which are not sized by the mesh are accumulated on the mesh belt 46, and are directed toward the arrow with the mesh belt 46. Transfer. The fine particles dropped from the mesh belt 46 are those containing relatively small or low density (resin particles or toners or additives, etc.) in the defibration, and are not used in the sheet manufacturing apparatus 100 for producing sheets. The mesh belt 46 moves at a specific speed V1 during the normal operation of manufacturing the sheet. In the normal operation, the sheet manufacturing apparatus 100 manufactures a sheet of a desired quality, in addition to the operation of the sheet manufacturing apparatus 100 to be described later, and the execution of the stop control. period. Therefore, the defibrated material defibrated by the defibrating unit 20 is sorted into the first sorting and the second sorting in the sorting unit 40, and the second sorting object is returned to the defibrating unit 20. Further, the removed matter is removed from the first sorting material by the first mesh forming portion 45. The remainder after removing the removed material from the first sorting is a material suitable for the production of a sheet, and the material is deposited on the webbing 46 to form the first web W1. The suction portion 48 attracts air from below the mesh belt 46. The suction unit 48 is coupled to the dust collecting unit 27 via the tube 23 . The dust collecting portion 27 is a filter type or a cyclone type dust collecting device that separates the fine particles from the air current. A collecting blower 28 (separating and suctioning portion) is provided downstream of the dust collecting portion 27, and the collecting blower 28 functions as a dust collecting suction portion that sucks air from the dust collecting portion 27. Further, the collection blower 28 discharges the discharge pipe 29 and discharges it to the outside of the sheet manufacturing apparatus 100. In this configuration, the air is sucked from the suction portion 48 by the dust collecting portion 27 by the collecting blower 28. In the suction portion 48, the fine particles passing through the mesh of the mesh belt 46 are attracted together with the air, and are transported to the dust collecting portion 27 through the tube 23. The dust collecting portion 27 separates and accumulates the fine particles passing through the mesh belt 46 from the air current. Therefore, on the mesh belt 46, the fibers from which the removed matter is removed from the first sorting material are deposited to form the first web W1. The suction by the trap blower 28 promotes the formation of the first web W1 on the web 46 and accelerates the removal of the removed material. The humidified air is supplied to the space including the drum portion 41 by the humidifying unit 204. The first sorting material is humidified inside the sorting unit 40 by the humidified air. Thereby, the adhesion of the first sorting material to the mesh belt 46 due to static electricity can be weakened, and the first sorting material can be easily peeled off from the mesh belt 46. Further, it is possible to suppress adhesion of the first sorting material to the inner walls of the rotating body 49 and the outer casing portion 43 due to static electricity. Further, the removed portion can be effectively sucked by the suction portion 48. Further, in the sheet manufacturing apparatus 100, the configuration of sorting and separating the first defibrated material and the second defibrated material is not limited to the sorting unit 40 including the drum portion 41. For example, it is also possible to adopt a configuration in which the defibrated material 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. For example, the configuration may be such that the fine particles contained in the first sorting material are removed from the first sorting by a classifier. In this case, for example, the second sorting object may be returned to the defibrating unit 20, and the removed material may be collected by the dust collecting unit 27, and the first sorted material from which the removed matter is removed may be sent to the tube 54. In the transport path of the mesh belt 46, on the downstream side of the sorting unit 40, air containing mist is supplied by the humidifying unit 210. The mist, which is a fine particle of water generated by the humidifying unit 210, descends toward the first mesh W1, and supplies the water to the first mesh W1. Thereby, the amount of water contained in the first web W1 can be adjusted, and adsorption of the fibers to the mesh belt 46 due to static electricity can be suppressed. The sheet manufacturing apparatus 100 includes a rotating body 49 that divides the first web W1 deposited on the mesh belt 46. The first mesh W1 is peeled off from the mesh belt 46 at the position where the mesh belt 46 is folded back by the roller shaft 47, and is separated by the rotary body 49. The first mesh W1 is a soft material in which the fibers are stacked and has a mesh shape, and the rotating body 49 unwinds the fibers of the first mesh W1 and is processed into a state in which the mixing portion 50 which will be described later is mixed with the resin. The configuration of the rotating body 49 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 49 is disposed at a position where the first mesh W1 peeled off from the mesh belt 46 is in contact with the blade. By the rotation of the rotating body 49 (for example, 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 is collided and broken, and the subdivided body P is generated. . Further, the rotating body 49 is preferably disposed at a position where the blades of the rotating body 49 do not collide with the mesh belt 46. For example, the distance between the front end of the blade of the rotating body 49 and the mesh belt 46 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 49 without causing damage to the mesh belt 46.  The subdivided body P divided by the rotating body 49 descends inside the tube 7, Then, it is transferred (transported) to the mixing unit 50 by the airflow flowing inside the tube 7.  also, For the space containing the rotating body 49, The humidified air is supplied by the humidifying unit 206. With this, It can suppress the fiber from being inside the tube 7 due to static electricity, Or the phenomenon of adsorption of the blades of the rotating body 49. also, As it passes through tube 7, The air having a higher humidity is supplied to the mixing portion 50, Therefore, the influence of static electricity can also be suppressed in the mixing unit 50.  The mixing unit 50 is provided with: Additive supply unit 52, Providing an additive comprising a resin; Tube 54, It is in communication with the tube 7, And for the flow of air containing the segment P; And a hybrid blower 56.  The subdivided body P is a fiber obtained by removing the removed material from the first sorting by the sorting unit 40 as described above. The mixing unit 50 mixes the resin-containing additive with the fibers constituting the subdivided body P.  In the mixing unit 50, The air flow is generated by the mixing blower 56, In tube 54, The subdivided body P is mixed while being mixed with the additive. also, The subdivided body P is unwound in the process of flowing inside the tube 7 and the tube 54 to become a finer fibrous shape.  The additive supply unit 52 (resin housing portion) is connected to an additive cartridge (not shown) that accumulates the additive. The additive inside the additive cartridge is supplied to the tube 54. The additive cartridge may be configured to be detachable from the additive supply unit 52. also, It may also have a composition for adding an additive to the additive card. The additive supply unit 52 temporarily stores an additive containing fine powder or fine particles inside the additive cartridge. The additive supply unit 52 has a discharge unit 52a (resin supply unit) that transports the temporarily stored additive to the tube 54.  The discharge unit 52a is provided with: Feeder (not shown), It delivers the additive stored in the additive supply portion 52 to the tube 54; And baffle (not shown), It opens and closes the conduit connecting the feeder to the tube 54. When the bezel is closed, The pipe or opening connecting the discharge portion 52a and the pipe 54 is closed. On the other hand, the additive supply unit 52 is blocked from supplying the additive to the tube 54.  In a state where the feeder of the discharge portion 52a is not operating, The supply of the additive to the tube 54 is not supplied from the discharge portion 52a. However, when a negative pressure is generated in the tube 54, etc., Even if the feeder of the discharge portion 52a is stopped, there is a possibility that the additive still flows to the tube 54. Therefore, by closing the discharge portion 52a, The flow of such additives can be reliably blocked.  The additive supplied from the additive supply unit 52 includes a resin 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 also be used singly or in an appropriate mixture. which is, Additives may also contain a single substance. Also a mixture, A plurality of particles composed of various single or plural substances may also be included. also, The additive may also be fibrous. It can also be in the form of a powder.  The resin contained in the additive is agglomerated by heating and melting to form a plurality of fibers. 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 are not attached to each other.  also, The additive supplied from the additive supply unit 52 is a resin other than the resin that binds the fibers. According to the type of sheet S manufactured, 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 also be colorless, Or a lighter color that appears to be colorless, It can be white.  By mixing the airflow generated by the blower 56, Subdivided body P descending from tube 7 The additive supplied from the additive supply unit 52 is sucked into the inside of the tube 54, And through the inside of the mixing blower 56. The airflow generated by the mixing blower 56 and/or the rotating portion of the hybrid blower 56 has a function of a rotating portion such as a blade. Mixing the fibers constituting the segment P with the additive, And the mixture (the mixture of the first sort and the additive) is transferred to the stacking portion 60 through the tube 54.  another, The mechanism for mixing the first sorting material with the additive is not particularly limited. It can also 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 can 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 is introduced into the mixture passing through the mixing portion 50 from the introduction port 62. Untangling the defibrated matter (fiber), The side of the air is dispersed 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 second mesh formation portion 70 with good uniformity.  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 41, 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 second mesh forming portion 70 is disposed below the drum portion 61. The second mesh forming portion 70 accumulates the passage passing through the stacking portion 60, The second web W2 (deposit) is formed. The second mesh forming portion 70 has, for example, a mesh belt 72 (belt), Roller shaft 74, And a suction mechanism 76.  The mesh belt 72 is a ring-shaped belt. Suspended from a plurality of rollers 74, It is conveyed in the direction indicated by the arrow in the figure by the rotation of the roller shaft 74. 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 descending from 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 in the action of manufacturing the sheet S.  The mesh of the mesh belt 72 is relatively small, It can be set to a size that does not pass the fibers or particles that are lowered by the majority of the rotating cylinder portion 61.  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 provided with a suction blower 77, By the attraction of the suction blower 77, The suction mechanism 76 generates a downward flow of air (air flow from the stacking portion 60 to the mesh belt 72).  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, Forming a downflow in the falling path of the mixture, It prevents the defibration or additives from becoming entangled in the fall.  The suction blower 77 (stacking suction portion) may discharge the air sucked from the suction mechanism 76 to the outside of the sheet manufacturing apparatus 100 through a collection filter (not shown). Or the air sucked by the suction blower 77 may be sent to the dust collecting portion 27, The removal of the air contained in the suction mechanism 76 is captured.  In the space including the drum portion 61, The humidified air is supplied by the humidifying unit 208. With the humidified air, The inside of the stacking portion 60 can be humidified, Suppressing adhesion of fibers or particles due to static electricity to the outer shell portion 63, And the fiber or particle can be quickly lowered to the mesh belt 72, A second mesh W2 having a better shape is formed.  As shown above, By passing through the stacking portion 60 and the second mesh forming portion 70 (the mesh forming step), On the other hand, a second mesh W2 containing a large amount of air and being in a soft expanded state is formed. The second web W2 deposited on the mesh belt 72 is conveyed to the sheet forming portion 80.  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 212. With this, The mist generated by the humidifying portion 212 is supplied to the second mesh W2, The amount of water contained in the second web W2 is adjusted. With this, The adsorption of the fibers to the mesh belt 72 due to static electricity can be suppressed.  The sheet manufacturing apparatus 100 is provided with a conveying unit 79 that conveys the second web W2 on the mesh belt 72 to the sheet forming unit 80. The transport unit 79 has, for example, a mesh belt 79a. Tension roller 79b, And a suction mechanism 79c.  The suction mechanism 79c is provided with a blower (not shown). The upward airflow is generated by the mesh belt 79a by the attraction of the blower. This airflow attracts the second mesh W2. With this, The second web W2 is separated from the web belt 72 and adsorbed to the web belt 79a. The mesh belt 79a is moved by the rotation of the tension roller 79b, The second web W2 is conveyed to the sheet forming portion 80. The moving speed of the mesh belt 72, The moving speed with the mesh belt 79a is, for example, the same. in this way, The conveyance unit 79 peels off and conveys the second web W2 formed on the mesh belt 72 from the mesh belt 72.  The sheet forming portion 80 forms the sheet S by the deposit deposited by the stacking portion 60. More specifically, The sheet forming unit 80 pressurizes the second web W2 deposited on the mesh belt 72 and conveyed by the conveying unit 79 to form the sheet S. In the sheet forming portion 80, 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 sheet forming unit 80 includes a pressurizing unit 82 that presses the second web W2, And a heating unit 84 that heats the second web W2 pressurized by the pressurizing unit 82.  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 pressurization. The density of the second web W2 is increased. One of the pair of press rolls 85 is a drive roll that is 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. 2 is formed.  in this way, The second web W2 formed by the stacking portion 60 is pressurized and heated by the sheet forming portion 80 to form a 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 80. 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 unit 94 cuts the sheet S that has passed through the first cutting unit 92, for example.  By cutting the portion 90, A single sheet S of a predetermined size such as A4 size is formed. The cut single sheet S is discharged to the storage unit 102.  In the above composition, The raw material is first coarsely crushed by the coarse crushing portion 12, And the sheet S is made from the raw material which is coarsely crushed, but, For example, it is also possible to use a fiber as a raw material to produce a sheet S.  E.g, It can be configured to use a fiber equivalent to the defibrated material defibrated by the defibrating unit 20 as a raw material. It can be put into the drum portion 41. It may be configured to use a fiber equivalent to the first residue separated from the defibrated material as a raw material. The tube 54 can be put in. In this case, By supplying fibers such as waste paper or pulp to the sheet manufacturing apparatus 100, Sheet S can be manufactured.  The accommodating portion 102 has: The accommodating portion body 103H, It is put into the sheet S from above, And stacking, Storage sheet S; And a sheet feeding portion 103M, Send it out (send, The sheet S in the accommodating portion main body 103H is discharged.  The sheet feeding portion 103M includes a pickup roller 103N, And one of the pair of transport rollers 103P disposed on the downstream side of the pickup roller 103N (on the side of the printing device 105), 103Q automatic conveying mechanism.  The pickup roller 103N is disposed above the sheet S in the housing portion main body 103H. It is supported by the rocking member 103Y and is rocked up and down. The pickup roller 103N is brought into contact with the uppermost sheet S' by energization downward by an energizing member (not shown). The pickup roller 103N is rotationally driven by the first drive motor 303X (FIG. 3). And sending the uppermost sheet S' piece by piece to the conveying roller 103P, 103Q side.  another, When the manufactured sheet S is supplied into the accommodating portion main body 103H, The pickup roller 103N retreats to the top against the ability to engage, Therefore, the supply of the sheet to the accommodating portion main body 103H is not hindered.  Transfer roller 103P, One of the 103Qs is a driving roller driven by the second driving motor 303Y (Fig. 3). The other is a driven roller. Transfer roller 103P, 103Q sends the sheet S' sent out by the pickup roller 103N to the printing apparatus 105.  The fed sheet S ′ is supplied to the printing apparatus 105 through a transport path (not shown) provided between the accommodating unit 102 and the printing apparatus 105 . With this, The sheet feeding unit 103M supplies the sheet S (S') in the storage unit 102 to the printing apparatus 105. which is, The sheet feeding unit 103M discharges the sheet S in accordance with the so-called FILO (First In Last Out).  3 is a block diagram showing the configuration of a control system of the sheet manufacturing apparatus 100.  The sheet manufacturing apparatus 100 is provided with: Control device 110, It has a main processor 111 that controls each part of the sheet manufacturing apparatus 100.  The control device 110 includes a main processor 111, ROM (Read Only Memory: Read-only memory) 112, And RAM (Random Access Memory: Random access memory) 113. The main processor 111 is a CPU (Central Procssing Unit: Central processing unit) and other arithmetic processing devices, Further, each unit of the sheet manufacturing apparatus 100 is controlled by executing a basic control program stored in the ROM 112. The main processor 111 can also be included as a ROM 112, It is composed of peripheral circuits such as RAM 113 or other system chips of IP cores.  The ROM 112 non-volatilely memorizes the program executed by the main processor 111. The RAM 113 forms a work area for use by the main processor 111. The data of the program or the processing object executed by the main processor 111 is temporarily memorized.  The non-volatile memory unit 120 memorizes a program executed by the main processor 111, Or data processed by the main processor 111. The non-volatile memory unit 120, for example, memorizes the setting data 121, And display information 122. The setting material 121 includes information for setting the operation of the sheet manufacturing apparatus 100. E.g, The setting material 121 includes characteristics of various sensors included in the sheet manufacturing apparatus 100, Or the threshold value and the like used in the processing of the abnormality are detected by the main processor 111 based on the detected values of the various sensors.  also, The setting data 121 includes a manufacturing start date (schedule) specified by an operator of the operation sheet manufacturing apparatus 100, And manufacturing conditions (density (basis weight) of sheet S, Shape (size, thickness), colour, Information on the amount of manufacture (number of pieces produced), etc.).  also, The setting data 121 also includes setting remaining amount information specifying the minimum remaining amount of the storage unit 102. The value of the set remaining amount is, for example, information set by an operator who operates the sheet manufacturing apparatus 100. The value of the set remaining amount is the information used in "Automatic Supplemental Control of Sheets" shown in Fig. 5 which will be described later.  The display material 122 is the screen material displayed on the display panel 116 (FIG. 3) by the main processor 111. The display material 122 is, for example, an operation state of the display sheet manufacturing apparatus 100, Various settings, Warning display and other information. The display data 122 can also be a fixed image data. Further, it is possible to set a profile for displaying a screen displayed by the main processor 111.  The touch sensor 117 detects a touch (contact) operation, Or press the operation. The touch sensor 117 is, for example, a pressure sensing type having a transparent electrode, Or a capacitive sensor, And arranged on the display surface of the display panel 116. When the touch sensor 117 detects the operation, The operation data including the number of operation positions or operation positions is output to the main processor 111. The main processor 111 is based on the output of the touch sensor 117. Detecting the operation of the display panel 116, And get the operating position. The main processor 111 is based on the operation position detected by the touch sensor 117, The GUI (Graphcal User Intertace:) is implemented on the display material 122 in the display panel 116. Graphical user interface) operation.  The control device 110 via the sensor I/F (Interface: The interface 114 is connected to a sensor provided in each part of the sheet manufacturing apparatus 100. The sensor I/F 114 takes the detected value of the sensor output and inputs it to the interface of the main processor 111. The sensor I/F 114 can also have an A/D that converts the analog signal of the sensor output into digital data (Analogue/Digital: Analog/digital) computer. also, The sensor I/F 114 can also supply drive current to each sensor. also, The sensor I/F 114 may also have an output value of each sensor obtained according to a sampling frequency specified by the main processor 111. And output to the circuit of the main processor 111.  Connecting the waste paper remaining amount sensor 301 to the sensor I/F 114, And a storage portion remaining amount sensor 303.  The waste paper remaining amount sensor 301 detects the remaining amount of the waste paper which becomes the raw material of the sheet S. When the remaining amount of the waste paper detected by the waste paper amount sensor 301 is lower than the set value, Informed that the waste paper is insufficient. The accommodating portion remaining amount sensor 303 detects the remaining amount of the sheet S stored in the accommodating portion 102.  The control device 110 notifies when the remaining amount of the sheet S detected by the accommodating portion remaining amount sensor 303 becomes a specific amount. also, The sheet S stored in the accommodating portion 102 that does not reach the set remaining amount is The control device 110 executes control that is automatically manufactured and added to the storage unit 102 ("sheet automatic replenishment control" shown in FIG. 6 to be described later).  The above configuration is an example. For example, the sheet manufacturing apparatus 100 may have other sensors, And the control device 110 can obtain the detected values of the sensors. E.g, The sheet manufacturing apparatus 100 may further include a sensor that detects the remaining amount of the additive in the additive supply unit 52, The sensor sheet manufacturing apparatus 100 stores a sensor for storing the amount of water in a tank (not shown) for humidifying water. also, The sheet manufacturing apparatus 100 may further include a temperature detected by the air flowing inside the sheet manufacturing apparatus 100, Air volume, Wind speed sensor.  The control device 110 is connected to each of the drive units included in the sheet manufacturing apparatus 100 via a drive unit I/F (Interface) 115. The driving unit of the sheet manufacturing apparatus 100 is a motor, Pump, Heater, etc.  In the drive unit I/F115, As a control object of the control device 110, Connected to the supply unit 10, Rough part 12, Defibration unit 20, Additive supply unit 52, Blower 315, Humidification unit 316, Rotary drive unit 317, Belt drive unit 318, And a breaking portion 319.  The supply unit 10 includes a drive unit such as a motor that rotates a roller shaft (not shown) provided in the supply unit 10 . The defibrating unit 20 includes a driving unit such as a motor that rotates a rotor (not shown) provided in the defibrating unit 20 . The additive supply unit 52 includes a motor that drives the screw feeder that sends the additive to the discharge unit 52a, A drive unit such as a motor or an actuator that opens and closes the discharge unit 52a. The blower 315 includes a defibrating unit blower 26, Capture blower 28, Mixing blower 56, Suction blower 77 and the like. The blowers may also be individually connected to the drive unit I/F 115. The humidifying portion 316 includes a humidifying portion 202, 204. 206, 208, 210, 212 and so on.  The drum drive unit 317 includes a drive unit such as a motor that rotates the drum unit 41. The belt drive portion 318 includes a motor that drives the mesh belt 46, A drive unit such as a motor that drives the mesh belt 72.  The breaking portion 319 includes a driving portion such as a motor that rotates the rotating body 49. also, A heater that heats the heating roller 86 may be connected to the driving portion I/F 115, Gasification humidifier, Spray humidifier, etc. Further, a feed water pump that supplies water to each humidifier may be connected to the drive unit I/F 115.  Furthermore, a pressing portion 82 is connected to the driving portion I/F 115, Heating unit 84, Cutting unit 90, The motor of the sheet feeding portion 103M (the first driving motor 303X, The second drive motor 303Y) or the like. The first drive motor 303X drives the pickup roller 103N, The second drive motor 303Y drives the transport roller 103P, One of the 103Q. The control device 110 controls the first and second drive motors 303X, The beginning of the rotation of 303Y, stop, And the speed of rotation.  FIG. 4 is a flow chart showing the basic operation of the sheet manufacturing apparatus 100.  After the control device 110 turns on the power of the sheet manufacturing apparatus 100 to execute the startup sequence, The action shown in Figure 4 can be started. As shown in Figure 4, When the control device 110 is input with a manufacturing instruction, Or to the pre-set manufacturing start date (step S1A; YES (yes)), Then, the manufacture of the sheet S is started (step S2A).  The control device 110 can input an instruction to start manufacturing via an operation panel such as the touch sensor 117, Or set the date of manufacture start and manufacturing conditions. The manufacturing conditions are the density (basis weight) of the sheet S, Shape (size, thickness), colour, Manufacturing amount (number of sheets manufactured), and the like.  also, The control device 110 does not input a manufacturing instruction, Or when it is not yet the date of manufacture (step S1A: no), Temporarily ending the process shown in Figure 4, The processing of step S1A is performed by vacating the time interval. Or may be configured to trigger the input of the manufacturing instruction. The processing after step S2A is performed.  In step S2A, The control device 110 manufactures the sheet S by operating the respective portions of the sheet manufacturing unit 101. In this case, The control device 110 adjusts the speed V2 of the mesh belt 72 of the second mesh forming portion 70, for example. Adjustment of the speed V1 of the mesh belt 46, 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 110 controls the color of the sheet S by controlling the type and amount of the coloring agent added by the additive supply unit 52. also, The control device 110 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 that conforms to predetermined manufacturing conditions is manufactured.  The manufactured sheet S is supplied to the accommodating portion 102. The control device 110 includes a counting sensor (not shown) that counts the sheet S, Or counting the number of times the cutting unit 90 is cut, etc. The amount of manufacture of the sheet S (the number of sheets produced) can be specified. then, The control device 110 determines whether or not the manufacture of the sheet S is ended (step S3A), At the end of the manufacturing situation, The operation of each part of the sheet manufacturing unit 101 is stopped (step S4A).  When the manufacturing is completed, the manufacturing amount of the sheet S reaches the amount that complies with the manufacturing conditions, The situation in which the manufacturing is stopped is indicated via the touch sensor 117, Or the situation when the manufacturing is stopped. According to the above, the sheet S is manufactured in a manner consistent with the manufacturing conditions, The manufactured sheet S is stored in the storage unit 102. The above is the basic operation of the sheet manufacturing apparatus 100.  The control device 110 can execute the "automatic replenishment control of the sheet" by automatically manufacturing the sheet S based on the remaining amount of the sheet S stored in the accommodating portion 102.  Figure 5 is a flow chart showing the automatic replenishment control of the sheet.  After the control device 110 turns on the power of the sheet manufacturing apparatus 100 to execute the startup sequence, The action shown in Figure 5 can be started. As shown in Figure 5, The control device 110 is based on the remaining amount detected by the storage portion remaining amount sensor 303. It is determined whether or not the remaining amount of the storage unit 102 has not reached the preset remaining amount (step S1B).  When the remaining amount of the accommodating portion 102 does not reach the set remaining amount (step S1B; Yes (YES)), The control device 110 specifies the type of the sheet S that does not satisfy the set remaining amount, The manufacturing amount of the sheet S is specified (step S2B).  The kind of the sheet S in this case is specific to the information other than the manufacturing amount in the manufacturing conditions of the specific sheet S, E.g, The density of the sheet S of the specific production object based on the setting material 121, Shape and color, etc. also, The manufacturing amount of the sheet S is specified to specifically set the remaining amount of the accommodating portion 102 to a value exceeding the remaining amount of the set remaining amount. For example, the value (number of pieces) that satisfies the set remaining amount is set based on the remaining amount detected by the accommodating portion remaining amount sensor 303. in this way, The manufacturing conditions of the sheet S to be produced are set.  then, The control device 110 starts the manufacture of the sheet S in accordance with the specific manufacturing conditions (step S3B). on the other hand, The control device 110 determines in step S1B that the storage unit 102 satisfies the set remaining amount (step S1B; No (NO)), Ending the process shown in Figure 5, The processing of step S1B is performed at intervals.  In step S3B, The control device 110 is the same as the above step S2 A, Each part of the sheet manufacturing part 101 is controlled and the sheet S is manufactured according to the manufacturing conditions. The manufactured sheet S is stored in the storage unit 102.  then, The control device 110 determines whether or not the manufacture of the sheet S is ended (step S4B), When the manufacturing is completed, the operations of the respective portions of the sheet manufacturing unit 101 are stopped (step S5B). The case where the manufacturing is ended is a case where the manufacturing amount of the sheet S reaches the target amount. According to the above, If the remaining amount of the accommodating portion 102 does not reach the set remaining amount, Automatically manufacturing the sheet S accommodated in the accommodating portion 102, And stored in the storage unit 102. The above is the automatic supplement control of the sheet.  FIG. 6 is a flow chart showing the basic operation of the printing apparatus 105.  After the control unit 105A of the printing apparatus 105 turns on the power of the printing apparatus 105 and executes the startup sequence, The action shown in Figure 6 can be started.  The control unit 105A inputs (receives) printed materials, Then, it is determined whether the supply target of the sheet to be printed is the sheet manufacturing apparatus 100 (the accommodating unit 102) or the manual insertion accommodating unit 104 (step S2C).  The determination of step S2C is applied to the information in the printed material that includes the supply target of the display sheet in advance. The method that the control unit 105A determines based on the information. or, A method of determining an appropriate supply target by the control unit 105A based on the sheet information (for example, size) of the printing target included in the printed material is applied. another, The printed materials contain the contents of ordinary printed materials. That is, the content of the print, The type (for example, size) of the sheet S of the printing object, And information such as the amount of printing (number of printed sheets).  The control unit 105A is in the case where the supply target of the sheet is the sheet manufacturing apparatus 100 (the storage unit 102) (step S2C; Yes), The information of the sheet S and the amount of printing (the number of printed sheets) of the printing target included in the specific printable material is used as the printing target information. It is sent to the sheet manufacturing apparatus 100 (step S3C). Subsequently, The control unit 105A is when the sheet S is supplied from the sheet manufacturing apparatus 100 (step S4C; Yes), Printing to the sheet S is started (step S5C). With this, The sheet S manufactured by the sheet manufacturing apparatus 100 prints an image based on printed materials.  on the other hand, The control unit 105A is in the case where the sheet S is not supplied (step S4C; no), Stand by until the sheet S is supplied. however, If the standby time exceeds the preset allowable time, It is preferable to perform a specific notification process. E.g, When the sheet manufacturing apparatus 100 cannot manufacture the sheet S to be printed due to insufficient amount of waste paper or the like, When the standby time exceeds the allowable time, Perform the above notification processing. Allow time is as long as the appropriate time is set.  also, In the determination of step S2C, The control unit 105A determines that the sheet supply target is the manual insertion storage unit 104 (step S2C; no), The manual insertion storage unit 104 requests the sheet to be printed (step S10C), And it moves to the process of step S4C. therefore, The control unit 105A supplies the sheet from the manual insertion storage unit 104 (step S4C; Yes), Printing to the sheet is started (step S5C). In the case of continuous printing of multiple films, The printing process is repeated for each piece (step S4C, S5C).  After starting printing, The control unit 105A determines whether or not the printing is ended (step S6C), When the printing is ended, the operations of the respective portions of the printing apparatus 105 are stopped (step S7C). The case where the printing is ended is, for example, a case where printing based on printed materials is completely completed. in this way, The printing apparatus 105 can use the sheet S manufactured by the sheet manufacturing apparatus 100, Alternatively, it is stored in a sheet that is manually inserted into the accommodating portion 104 and printed.  another, The manual insertion accommodating portion 104 may be a paper feeder built in the printing device 105. Further, it may be a paper feeder externally connected to the printing device 105.  also, In step S1C, The control device 110 is in the case where the printed material is not input (step S1C; no), Ending the process shown in Figure 6, And the processing of step S1C is performed at the time interval. Or may be configured to trigger the input of printed materials, The processing after step S2C is performed.  also, The transmission of the printing target information in the above step S3C is a paper supply request to the control device 110 of the sheet manufacturing apparatus 100, In other words, A sheet discharge request from the accommodating portion 102, Or request for use of sheet S.  however, The sheet S accommodated in the accommodating portion 102 is sent out from the uppermost sheet S'. therefore, When the sheet manufacturing unit 101 supplies the sheet to the storage unit 102 at the same time, And discharging from the storage unit 102 to the sheet of the printing device 105, There is a transport error such as blockage or double feed. Or on sheet S, S' produces wrinkles and the like.  therefore, In this composition, As the paper feed control of the storage unit 102, The control device 110 can realize the "manufacturing priority control" in which the sheet is not discharged from the accommodating portion 102 during the supply of the sheet to the accommodating portion 102, The "printing priority control" of the sheet is not supplied to the accommodating portion 102 during the printing operation.  In the setting data 121 stored in the non-volatile memory unit 120, Contains information on the conditions of paper supply for which specific execution of "manufacturing priority control" and "printing priority control" can be specified. The paper feed condition information is set by an operator or the like who operates the sheet manufacturing apparatus 100. The desired control is selected by the operator or the like.  Fig. 7 is a flow chart showing the operation of manufacturing priority control.  There is a paper supply request from the printing device 105 (a sheet discharge request, In the case of the use of the sheet S,) The control device 110 determines whether it is in the manufacturing sheet S, The sheet S is supplied to the accommodating portion 102 (step S1F). When the determination in step S1F is a negative result (step S1F; no), The control device 110 permits paper feeding to the control unit 105A of the printing device 105 (step S2F), The sheet S (S') is supplied to the printing device 105 by the sheet feeding portion 103M (step S3F).  The processing of the step S2F is, for example, the processing by the control device 110 to the control unit 105A of the printing apparatus 105 to transmit information (feeding permission information) for the purpose of paper feeding. According to the above processing, In the case of non-manufactured sheet S, Or even if it is not in the case of being supplied to the accommodating portion 102 in the sheet S, The sheet S (S') is supplied to the printing device 105, And you can start printing quickly.  on the other hand, When the determination in step S1F is a positive result (step S1F; Yes), The control device 110 stands by until the manufacture of the sheet S is stopped, Or not supplying the state of the sheet S to the accommodating portion 102 (step S4F; no).  The control device 110 stops the manufacture of the sheet S, Or when the state of the sheet S is not supplied to the accommodating portion 102 (step S4F; Yes), The process proceeds to step S2F. With this, Manufacturing of the preferential sheet S (including supplying the sheet to the accommodating portion 102), And feeding the sheet to the accommodating portion 102 in accordance with the timing of the shift, And discharging the sheet from the accommodating portion 102.  After the processing of step S3F, The control device 110 determines whether or not the paper feed to the printing device 105 is ended (step S5F), At the end of the paper supply situation, The operation of the sheet feeding portion 103M is stopped. The paper feed is stopped (step S6F). The case where the paper feed is ended is a case where the sheet S (S') equivalent to the amount of printing (the number of sheets) has been fed to the printing apparatus 105. The above is the action of manufacturing priority control.  Fig. 8 is a flow chart showing the operation of the print priority control. another, The same control as that of Fig. 7 is denoted by the same reference numeral.  There is a paper supply request from the printing device 105 (a sheet discharge request, In the case of the use of the sheet S,) The control device 110 determines whether it is in the manufacturing sheet S, The sheet S is supplied to the accommodating portion 102 (step S1F). When the determination in step S1F is a negative result (step S1F; no), The control device 110 permits paper feeding to the control unit 105A of the printing device 105 (step S2F). Subsequently, The control device 110 sends the sheet S (S') stored in the storage unit 102 to the printing device 105. The paper is fed to the printing device 105 (step S3F).  on the other hand, When the determination in step S1F is a positive result (step S1F; Yes), The control device 110 interrupts the manufacture of the sheet S, The supply of the sheet to the accommodating portion 102 is interrupted (step S4G). Subsequently, The control device 110 moves to the processing of step S2F. With this, After the supply of the sheet to the accommodating portion 102 is stopped, The sheet S (S') in the accommodating portion 102 is supplied to the printing device 105. With this, Preferentially feeding paper to the printing device 105, And feeding the sheet to the accommodating portion 102 in accordance with the timing of the shift, And discharging the sheet from the accommodating portion 102.  After the processing of step S3F, The control device 110 determines whether or not the paper feed to the printing device 105 is ended (step S5F), At the end of the manufacturing situation, The paper feed is stopped (step S6F). Subsequently, The control device 110 determines whether or not the sheet supply to the storage unit 102 is interrupted (step S7G). In the step S7G, When the control device 110 interrupts the manufacture of the sheet S by performing the processing of step S4G, It is determined that the supply to the sheet of the accommodating portion 102 is interrupted.  If it is determined that the sheet supply is interrupted (step S7G; Yes), Then the control device 110 restarts the manufacture of the sheet S, The sheet is again supplied to the accommodating portion 102 (step S8G). on the other hand, When it is determined that the supply is not interrupted (step S7G; no), The control device 110 stops the operation of the print priority control. The above is the action of printing priority control.  With the print priority control, That is, when the sheet S is manufactured according to the flow shown in FIG. 4 or FIG. 5, The sheet supply to the accommodating portion 102 may be interrupted and paper may be fed to the printing device 105. also, When the supply of the sheet to the accommodating portion 102 is resumed when the paper feeding to the printing device 105 is completed, Therefore, the manufacture can be continued until a predetermined amount of the sheet S is produced.  FIG. 9 is a flowchart showing the operation of the sheet manufacturing apparatus 100 when the printing target information is acquired from the printing apparatus 105 (step S3C of FIG. 6).  As shown in Figure 9, When the control device 110 inputs (receives) print target information (sheet discharge request, When the use of the sheet S is requested) (step S1D; Yes), Based on the sheet S and the amount of printing of the printing object specified by the printing target information, 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 accommodating portion 102.  E.g, When the sheet S stored in the storage unit 102 is equal to or larger than the printing amount, the control device 110 It is determined that it is not necessary to manufacture the sheet S (step S2D; no). In this case, The control device 110 starts the control of feeding the sheet S of the printing target stored in the storage unit 102 to the printing device 105 (step S3D).  then, The control device 110 determines whether or not the paper feed is ended (step S4D). When the control device 110 supplies the sheet S of the printing target to the printing device 105, It is determined that the paper feed is ended (step S4D; Yes) the paper feed is stopped (step S5D).  In step S2D, When the sheet S stored in the storage unit 102 does not reach the printing amount (the amount of printing is not satisfied), It is determined that it is necessary to manufacture the sheet S (step S2D; Yes). also, When the storage unit 102 does not store the sheet S to be printed, the control device 110 determines that it is necessary to manufacture the sheet S (step S2D; Yes).  When it is determined that it is necessary to manufacture the sheet S (step S2D; Yes), The control device 110 moves to step S6D, Insufficient sheet S is specified as a sheet to be manufactured, And specific to ensure the target manufacturing quantity of the number of pieces. The target manufacturing quantity can also be the same as the number of defects. It can also be set to more than the number of pieces.  then, The control device 110 starts the manufacture of the sheet S to be manufactured (step S7D).  also, The control device 110 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 part of the sheet manufacturing unit 101 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 110 starts the control of feeding the manufactured sheet S to the printing device 105 via the storage unit 102 (step S10D). also, The control device 110 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 operation of the sheet feeding unit 103M is stopped to stop the paper feeding (step S12D). The case where the paper feed is ended is a case where the sheet S corresponding to the number of sheets of the printing amount is supplied to the printing apparatus 105. According to the above, When the sheet S of the printing object is insufficient, Can produce insufficient sheet S, And feeding paper to the printing device 105.  As shown in the above description, The sheet manufacturing apparatus 100 of the present embodiment includes: Sheet manufacturing unit 101, It manufactures sheet S; The storage unit 102, Stacked, Storing the sheet S produced by the sheet manufacturing unit 101; And a sheet feeding portion 103M, The sheet S' stored in the uppermost portion of the accommodating portion 102 is sent out. And, The control device 110 (control unit) of the sheet manufacturing apparatus 100 controls the supply of sheets from the sheet manufacturing unit 101 to the storage unit 102 in a staggered timing. And the sheet is discharged by the sheet feeding portion 103M.  According to this configuration, Since the sheet S is manufactured and housed in the accommodating portion 102, Therefore, the sheet S can be pre-manufactured beforehand. The manufacturing time of the sheet S is not easily restricted by the use time of the sheet S (the period of printing).  The sheet manufacturing apparatus 100 is preferably disposed on a waste paper that produces a material suitable for the sheet S. Also, use the office of the sheet S or the like. With this, It can realize the printing of the cycle corresponding type, Or office paper recycling.  E.g, When the sheet manufacturing apparatus 100 is installed in an office, The manufacture of the sheet S can be carried out at a time when the surrounding people are less. A sufficient sheet S is supplied to the printing apparatus 105 during a period of a large number of people (a period in which printing is performed). Further, the sheet S can be manufactured in advance at a time when the electricity rate is low.  also, Since the accommodating portion 102 is constituted by a so-called FILO discharge sheet S, Therefore, the appropriate sheet S can be supplied to the printing apparatus 105 by pre-manufacturing the sheet S for printing in advance. And, The sheet is not supplied to the accommodating portion 102, Simultaneously discharging the sheet from the storage unit 102, Can suppress the occurrence of transport errors, Or on sheet S, S' produces defects such as wrinkles.  also, The control device 110 is as described in steps S1F to S2F of FIGS. 7 and 8 . When the sheet is not supplied to the accommodating portion 102, The sheet of the sheet feeding portion 103M is allowed to be discharged. With this, The sheet S can be discharged from the accommodating portion 102 while the sheet is not being supplied to the accommodating portion 102.  which is, In the manufacture of the sheet S, However, the sheet S is not supplied to the accommodating portion 102, And any of the cases in the non-manufactured sheet S, The sheet feeding portion 103M is allowed to discharge the sheet. With this, The sheet S in the accommodating portion 102 can be quickly supplied to the printing device 105 (use side). therefore, The sheet S can be quickly discharged in accordance with a paper supply request from the printing device 105 (a request for use of the sheet S).  also, In the manufacturing priority control shown in Figure 7, When there is a paper supply request (sheet discharge request), If it is made in sheet S, And supplying the sheet S to the accommodating portion 102, The sheet feeding portion 103M is not allowed to discharge the sheet. Therefore, the manufacture of the sheet S can be preferentially performed. E.g, When the sheet manufacturing unit 101 of the present configuration interrupts the manufacture of the sheet S, The amount of accumulation of the mesh W2 before and after the interruption may vary. There is a change in the state of the sheet S. By prioritizing the manufacture of the sheet S, The state change of the sheet S due to the influence of the manufacturing interruption can be suppressed.  another, In step S1F of FIG. 7, It is explained whether it is determined whether or not the sheet S is manufactured and supplied to the accommodating portion 102 in the sheet S, But it is not limited to this, E.g, It is also possible to determine whether it is the processing in the manufacture of the sheet S, Or it is determined whether or not any of the processes in the sheet S is supplied to the accommodating portion 102. In this case, In step S4F of FIG. 7, When it becomes a state in the non-manufactured sheet S, Or when the state in the sheet S is supplied to the accommodating portion 102, Move to the processing of the next step S2F. According to this configuration, the production of the sheet S can be preferentially performed.  also, In the print priority control shown in Figure 8, When there is a paper supply request (sheet discharge request), When the sheet S is manufactured and supplied to the accommodating portion 102, When the manufacturing is interrupted and the supply of the sheet to the storage unit 102 is interrupted, The sheet feeding portion 103M is allowed to discharge the sheet. According to this configuration, The sheet can be discharged from the storage unit 102 in priority. And printing can be performed more quickly.  another, When the state of the sheet S is changed due to the interruption of the manufacturing, Preferably, the portion corresponding to the changed portion is cut by the cutting portion 90, And discharged to the outside of the accommodating portion 102.  also, The control device 110 is based on the remaining amount of the sheet S accommodated in the accommodating portion 102, The sheet manufacturing unit 101 is caused to manufacture the sheet S. According to this configuration, Can automatically replenish the sheet S, It is easy to eliminate the shortage of the sheet S.  Furthermore, Control device 110 according to a print request (paper feed request, Or the use of the sheet S) to manufacture the sheet S of the printing object (the object to be used), The sheet S is supplied to the printing device 105 by the sheet feeding portion 103M. According to this configuration, The sheet S corresponding to the request from the printing device 105 (use side) can be manufactured as needed, The desired sheet S is supplied as quickly as possible. therefore, Suppress printing from the middle of the process, Or the situation in which the waiting time for printing is prolonged, It is easy to quickly complete the use of printing and the like.  also, Control device 110 is shown in Figure 9, The sheet S of the specific printing object is based on the printing information of the specific sheet S, that is, the printing target information (using the object information), The sheet manufacturing unit 101 is caused to manufacture the sheet S. With this, The sheet S of the printing object can be easily specified, Also, the sheet S consumed by printing can be preferentially manufactured.  Here, Since the accommodating portion 102 of the present configuration discharges the sheet S by FILO, Therefore, the sheet S to be subsequently produced, that is, the sheet S to be manufactured can be sequentially supplied to the printing apparatus 105. therefore, Even if the sheet S of the non-printing target remains in the accommodating portion 102, It is also possible to supply the appropriate sheet S to the printing apparatus 105 by newly manufacturing the sheet S of the printing target.  also, Control device 110 is shown in Figure 9, Specific print volume (usage) based on print object information, The amount of manufacture of the sheet manufacturing unit 101 is controlled based on the amount of printing. With this, It is easy to specify the amount of printing, Further, it is possible to preferentially manufacture the sheet S in an amount corresponding to the amount of printing.  also, Since the printed object information is the information contained in the printed material supplied to the printing device 105, Therefore, the sheet S of the printing target, the amount of printing, and the like can be specified accurately.  also, The sheet manufacturing system 1 has a sheet manufacturing apparatus 100, And a printing apparatus 105 (printing unit) that prints the sheet S (S') discharged from the accommodating portion 102 of the sheet manufacturing apparatus 100. With this, As mentioned above, The sheet is supplied to the accommodating portion 102, The sheet discharged from the accommodating portion 102 is shifted, It can suppress defects such as transport errors. also, The sheet S can be manufactured and discharged as needed in accordance with a printing request.  also, Since the sheet manufacturing part 101 can manufacture density (basis weight), size, a sheet S having at least one of thickness and color, Therefore, it is easy to respond according to the requirements of using the sheet S side.  also, The raw material of the sheet S is not particularly limited to the range that can be produced. Furthermore, In order for the sheet manufacturing part 101 to manufacture a sheet S having different raw materials, The supply unit 10 may have a configuration capable of supplying various raw materials. With this, The sheet S can be produced in accordance with the raw material (material) required to use the side of the sheet S.  also, The sheet manufacturing unit 101 has: Defibration unit 20, It defibrates the coarsely divided raw material in air; a mesh forming portion 45, 70, Dissolving the defibrated material defibrated by the defibrating unit 20 to form a mesh; And a sheet forming portion 80, It forms a sheet S from a mesh. With this, The sheet manufacturing unit 101 is configured in a dry manner. Compared with the case of a so-called wet type, No need to or simplify water related equipment, It is more suitable for setting in the office.  (Second Embodiment) Fig. 10 is a view showing a sheet manufacturing system 1 according to a second embodiment. another, In the following description, The same portions as those in the first embodiment are denoted by the same reference numerals, and their description will be omitted. And explain the different parts.  This sheet manufacturing system 1 has a buffer 501 that temporarily stores the sheet S manufactured by the sheet manufacturing portion 101.  The damper 501 is disposed on the upstream side of the accommodating portion 102 of the manufacturing step of the sheet S, More specifically, It is provided between the heating part 84 and the cutting part 90. The damper 501 has a mechanism for winding up the sheet S formed of the sheet forming portion 80 including the heating portion 84, and the like. And by temporarily taking up the sheet S, The sheet S can be prevented from moving to the cutting portion 90. This buffer 501 is controlled by the control device 110.  In the second embodiment, The processing of the step S4G (manufacturing interruption) in the flowchart shown in Fig. 8 is different from the processing of the step S8G (restarting the supply of the sheet).  As the processing of step S4G, The control device 110 continues the manufacture of the sheet S, Further, the sheet S is stored in the buffer 501, and the supply of the sheet to the accommodating portion 102 is interrupted.  also, As the processing of step S8G, The control device 110 supplies the sheet S stored in the buffer 501 to the storage unit 102 via the cutting unit 90. On the other hand, the sheet is supplied to the accommodating portion 102 again.  With this, The manufacture of the sheet S can be continued, And interrupting the supply of the sheet to the accommodating portion 102, The sheet is discharged from the accommodating portion 102. another, The configuration of the buffer 501 is not limited to the mechanism for winding up the sheet S, Other configurations can also be applied. also, The position of the damper 501 is not limited to be between the heating portion 84 and the cutting portion 90. The damper 501 may be disposed in another place within a range in which the sheet supply to the accommodating portion 102 can be interrupted.  (Third Embodiment) Fig. 11 is a view showing a sheet manufacturing system 1 according to a third embodiment.  The third embodiment differs from the first embodiment in that: The sheet manufacturing unit 101 is of an electrostatic type. The storage unit 102 is not provided. FIG. 12 is a schematic view showing a main part of the sheet manufacturing unit 101.  The sheet manufacturing unit 101 electrostatically transfers the fiber-containing material as a raw material to the conveyance belt 401 (transferable body). And after the fiber-containing material is appropriately formed into the ink receiving layer, the surface property is adjusted, and then processed. Thereby, the sheet S is produced.  The sheet manufacturing unit 101 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 101, The fiber-containing material is electrostatically transferred from the carrier 420 to the transfer target (transport belt 401). With this, The amount of adhesion of the fiber-containing material adhering to the transfer target (transport belt 401) can be prevented from being uneven. which is, The fiber-containing material does not adhere excessively or insufficiently 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 ink accommodating layer 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 bonds the cellulose fibers to each other to form a porous ink containing layer. Adjusting the hydrophobicity of the ink containing layer by a hydrophobic material, Balance of hydrophilicity, Suppressing excessive wet diffusion or shrinkage of the ink when the ink of the sheet S is imparted, It is excellent in the absorption of ink. Furthermore, The hydrophobic material is coated with cellulose fibers, And the charging characteristics of the composite are stabilized. With this, The ink containing layer can be formed well 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 12, The supply unit 410 will store the storage unit 412, Mixer 413 (Agitator), Roller shaft 414, The first carrier 415, The blade 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 shaft 414. There is a potential difference between the first carrier 415 and the roller shaft 414. And the static electricity adheres to the fiber-containing material. The blade 416 adjusts (thickness) the thickness (adhesion amount) of the fiber-containing material attached 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 is attached to the fiber-containing material. The carrier body 420 is a rotating roller shaft 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 portion 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. And the thickness of the fiber-containing material is set to be uniform, And adjusted to a uniform thickness of the ink containing layer.  The conveyor belt 401 is composed of a belt of a ring shape. And transported by a plurality of rollers 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 material of such a constitution 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: Leveling 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 an ink containing layer curing portion 434, It is cured by an ink containing layer composed of a layered fibrous material. The leveling processing unit 431 is a leveling roller 435 having at least a metal surface on the outer peripheral surface thereof. Smoothing the surface of the fiber-containing material by the leveling roller 435, The fiber-containing material is neutralized via ground wire 436.  The pressurizing treatment portion 432 bonds the fiber-containing materials to each other by 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 ink containing layer 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 energization of the heater 441, And heating the ink containing layer by the curing roller 440 on one side, The ink containing layer is pressurized in the direction in which the layer thickness is reduced. With this, The thermoplastic resin in the ink containing layer is melted, And after the molten thermoplastic resin passes through the curing roller 440, For example, it is naturally cooled to form and solidify. in this way, Making a fibrous material having an ink containing layer that is not excessively or insufficiently 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 unit 101 is compared with the sheet manufacturing unit 101 of the first embodiment. Because there is no need to dismantle, sorting, attract, And mesh formation, etc. Therefore, it is easy to shorten the manufacturing time of the sheet S. therefore, By Figure 4, When the control sheet shown in FIGS. 5 and 9 is used to manufacture the sheet S, The sheet S can be manufactured in a short time.  E.g, When performing the control shown in Figure 9, That is, the printing target information (paper feed request, from the printing device 105 (use side), Or the case of the use of the sheet S,) The time from the start of the manufacture of the step S7D to the stop of the manufacture of the step S9D is a short time. therefore, Without the configuration of the storage portion 102, Sheet S can be manufactured as needed, And it is quickly supplied to the printing device 105. therefore, It is easy to manufacture the sheet S as needed for the request from the printing apparatus 105, And it is supplied to the printing device 105 as needed. also, Since there is no storage unit 102, Therefore, it is easy to reduce the size and space of the sheet manufacturing apparatus 100.  also, The sheet manufacturing unit 101 is also a dry type that does not use water as much as possible, as in the first embodiment. Therefore, water-related equipment is not required or simplified. It is more suitable for setting in the office.  another, Each of the above embodiments is only a specific embodiment of the present invention described in the scope of the patent application. Not limiting the inventor, All of the configurations described in the respective embodiments are not limited to the 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.  In various embodiments, The case where the sheet manufacturing unit 101 is connected to the single storage unit 102 will be described. But it is not limited to this, It is also possible to connect a plurality of storage portions 102.  When a plurality of storage portions 102 are connected, The manufactured sheet S can be separately stored in the plurality of storage portions 102 in accordance with various standards such as the type or the printing order. Various sheets S can be preliminarily manufactured before printing. also, The control device 110 for each storage unit 102, Similar to the above embodiments, The sheet is supplied from the sheet manufacturing unit 101 to the accommodating unit 102 by shifting the timing control. And the sheet feeding portion 103M discharges the sheet, It is not good for suppressing transport errors.  Further, any one of the plurality of accommodating portions 102 may be a accommodating portion for taking out which is detached by the user. In this case, The user can take out the sheet S from the take-out accommodating portion, It is installed in any printing device or the like and used.  E.g, When the sheet manufacturing system 1 is installed in an office, The printing device is also present at a position away from the sheet manufacturing system 1. By providing the storage unit for taking out, Each user can use the recycled sheet S in a printing device that is located at a remote location. It is also possible to promote the use of the sheet S.  also, The use side device using the sheet S manufactured by the sheet manufacturing apparatus 100 is not limited to the printing apparatus 105, A device capable of using the sheet S can be widely applied.  also, The sheet manufacturing apparatus 100 may be configured to manufacture 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 also be used as a recording paper for the purpose of taking notes or printing (for example, PPC (Plain Paper Copy: Plain paper photocopying) paper) paper used, Also for 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, In various embodiments, The case of having the dry sheet manufacturing part 101 is explained. However, it is not limited to this. For example, it may have a purpose of putting the raw material containing the fiber into the water. A sheet manufacturing unit for producing a sheet by a wet paper making method which is reconstituted by fiber separation.  also, At least a part of the functional blocks shown in FIG. 4 can also be implemented by hardware. It can also be realized by the cooperation of hardware and software. It is not limited to the configuration of the hardware resources that are independent of the configuration as shown. also, The program executed can also be memorized in the non-volatile memory, Or other memory device (omitted from illustration). Further, it may be configured to execute a program stored in the external device via the communication unit.

1‧‧‧Sheet Manufacturing System

2‧‧‧ tube

3‧‧‧ tube

7‧‧‧ tube

8‧‧‧ tube

9‧‧‧Bowl

10‧‧‧Supply Department

12‧‧‧Grade

13‧‧‧Bowl

14‧‧‧

20‧‧‧Defibration Department

22‧‧‧Import

23‧‧‧ tube

24‧‧‧Export

26‧‧‧Defibration blower

27‧‧‧Dust collection department

28‧‧‧ Capture blower

29‧‧‧ tube

40‧‧‧Sorting Department

41‧‧‧Turning Department

42‧‧‧Import

43‧‧‧Shell Department

44‧‧‧Export

45‧‧‧1st mesh formation

46‧‧‧Net belt

47‧‧‧ Roller

48‧‧‧Attraction

49‧‧‧Rotating body

50‧‧‧Mixed Department

52‧‧‧Additive Supply Department

52a‧‧‧Exporting Department

54‧‧‧ tube

56‧‧‧Mixed air blower

60‧‧‧Stacking Department

61‧‧‧Turning Department

62‧‧‧Import

63‧‧‧Shell Department

70‧‧‧2nd mesh formation

72‧‧‧Net belt

74‧‧‧ Roller

76‧‧‧sucking mechanism

77‧‧‧Suction blower

79‧‧‧Transportation Department

79a‧‧‧ mesh belt

79b‧‧‧ tension roller

79c‧‧‧ suction mechanism

80‧‧‧Sheet Forming Department

82‧‧‧ Pressurization

84‧‧‧heating department

85‧‧‧pressure roller

86‧‧‧heating roller

90‧‧‧cutting department

92‧‧‧1st cut-off

94‧‧‧2nd cut-off

95‧‧‧Export

96‧‧‧Exporting Department

100‧‧‧Sheet manufacturing equipment

101‧‧‧Sheet Manufacturing Department

102‧‧‧ 收纳 department

103H‧‧‧Storage Department Body

103M‧‧‧Sheet delivery department

103N‧‧‧ picking roller

103P‧‧‧Transport roller

103Q‧‧‧Transport roller

103Y‧‧‧Shake member

104‧‧‧Manual insertion into the storage unit

105‧‧‧Printing device (use side device)

105A‧‧‧Control Department

110‧‧‧Control device (control department)

111‧‧‧Main processor

112‧‧‧ROM

113‧‧‧RAM

114‧‧‧Sensor I/F

115‧‧‧Drive Department I/F

116‧‧‧ display panel

117‧‧‧ touch sensor

120‧‧‧Non-volatile memory

121‧‧‧Setting information

122‧‧‧Display information

140‧‧‧Memory Department

202‧‧‧ humidification department

204‧‧‧ humidification department

206‧‧‧ humidification department

208‧‧‧ humidification department

210‧‧‧Humidification Department

212‧‧‧ humidification department

301‧‧‧Waste Paper Remaining Sensor

303‧‧‧Receiving unit residual sensor

303X‧‧‧1st drive motor

303Y‧‧‧2nd drive motor

315‧‧‧Blowers

316‧‧‧ humidification department

317‧‧‧Turn Drive Department

318‧‧‧Belt Drive Department

319‧‧‧parts

343A‧‧‧1st storage drive motor

343B‧‧‧2nd storage drive motor

343C‧‧‧3rd storage drive motor

401‧‧‧Transporting belt (transferred body)

402‧‧‧roller

410‧‧‧Supply Department

411‧‧‧ Shell Department

412‧‧‧Storage Department

413‧‧‧Mixer

414‧‧‧ Roller

415‧‧‧1st carrier

416‧‧‧blade

420‧‧‧ Carrying body

421‧‧‧ outer perimeter

422‧‧‧Power Department

423‧‧‧Exposure Department

424‧‧‧Transfer Department

430‧‧‧Reprocessing Department

431‧‧‧Leveling Processing Department

432‧‧‧ Pressurization Department

433‧‧‧ Semi-curing treatment department

434‧‧‧Ink containment layer curing section

435‧‧‧ leveling roller

436‧‧‧ Ground

437‧‧‧Pressure roller

438‧‧‧室

439‧‧‧heater

440‧‧‧curing roller

441‧‧‧heater

501‧‧‧buffer

911‧‧‧ Roller

F‧‧‧Transfer direction

P‧‧‧Subdivision

R‧‧‧ arrow

S‧‧‧Sheet

S'‧‧‧Sheet

S1A‧‧‧ steps

S1B‧‧‧ steps

S1C‧‧‧ steps

S1D‧‧‧ steps

S1F‧‧‧ steps

S2A‧‧‧ steps

S2B‧‧ steps

S2C‧‧‧ steps

S2D‧‧‧ steps

S2F‧‧‧ steps

S3A‧‧‧ steps

S3B‧‧ steps

S3C‧‧‧ steps

S3D‧‧‧ steps

S3F‧‧‧ steps

S4A‧‧‧ steps

S4B‧‧‧ steps

S4C‧‧‧ steps

S4D‧‧‧ steps

S4F‧‧‧ steps

S4G‧‧‧ steps

S5B‧‧‧ steps

S5C‧‧‧ steps

S5D‧‧‧ steps

S5F‧‧‧ steps

S6C‧‧‧ steps

S6D‧‧‧ steps

S6F‧‧‧ steps

S7C‧‧‧ steps

S7D‧‧‧ steps

S7G‧‧‧ steps

S8D‧‧‧ steps

S8G‧‧‧ steps

S9D‧‧‧ steps

S10C‧‧‧ steps

S10D‧‧‧ steps

S11D‧‧‧ steps

S12D‧‧‧ steps

V1‧‧‧ speed

V2‧‧‧ speed

W1‧‧‧1st mesh

W2‧‧‧2nd mesh

Fig. 1 is a view showing a sheet manufacturing system of a first embodiment. Fig. 2 is a schematic view showing the configuration of a sheet manufacturing unit and a housing unit. Fig. 3 is a block diagram showing the configuration of a control system of a sheet manufacturing apparatus. Fig. 4 is a flow chart showing the basic operation of the sheet manufacturing apparatus. Figure 5 is a flow chart showing the automatic replenishment control of the sheet. Figure 6 is a flow chart showing the basic operation of the printing apparatus. Fig. 7 is a flow chart showing the operation of manufacturing priority control. Fig. 8 is a flow chart showing the operation of the print priority control. Fig. 9 is a flow chart showing the operation of the sheet manufacturing apparatus when the printing target information is acquired. Fig. 10 is a view showing a sheet manufacturing system of a second embodiment. Fig. 11 is a view showing a sheet manufacturing system of a third embodiment. Fig. 12 is a schematic view showing a main part of a sheet manufacturing unit according to a third embodiment.

Claims (7)

A sheet manufacturing apparatus comprising: a sheet manufacturing unit that manufactures a sheet; a sheet feeding unit that feeds a sheet produced by the sheet manufacturing unit to a use side of the sheet; and a control unit; The sheet manufacturing unit manufactures the sheet according to a request from the use side, and the sheet is fed to the use side by the sheet feeding unit. The sheet manufacturing apparatus according to claim 1, wherein the control unit acquires the use target information related to the sheet to be used, specifies the sheet to be used based on the use target information, and causes the sheet manufacturing unit to manufacture the use. The sheet of the object. The sheet manufacturing apparatus according to claim 1 or 2, wherein the control unit acquires the use target information related to the sheet to be used, specifies a usage amount based on the use target information, and controls the sheet manufacturing unit based on the usage amount. The amount of manufacturing. A sheet manufacturing system comprising: a sheet manufacturing unit that manufactures a sheet; a supply unit that feeds a sheet produced by the sheet manufacturing unit; and a printing unit that prints a sheet fed from the supply unit And a control unit that causes the sheet manufacturing unit to manufacture a sheet to be printed, and supplies the sheet to the printing unit by the supply unit. The sheet manufacturing system of claim 4, wherein the control unit acquires print target information related to a sheet to be printed, specifies a sheet to be printed based on the print target information, and causes the sheet manufacturing unit to manufacture the print. The sheet of the object. The sheet manufacturing system according to claim 4, wherein the control unit acquires print target information related to a sheet to be printed, specifies a print amount based on the print target information, and controls the sheet manufacturing unit based on the print amount. The amount of manufacturing. The sheet manufacturing system of claim 5 or 6, wherein the print target information is information included in the print material supplied to the printing unit.