JP2014134769A - Developer storage unit, developing device, process cartridge, and image forming apparatus - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a developer storage unit that has a long life without increasing the size of an image forming apparatus, and to provide the others.SOLUTION: A developer storage unit for storing developer comprises: a sealing member having an opening for discharging developer and storing developer, the sealing member configured to seal an opening; and a frame body 40 having a first frame body 17 and a second frame body 18, accommodating the developer storage container 26 in a space defined by fitting the first frame body 17 to the second frame body 18, and storing developer discharged from the developer storage container 26 unsealed. In the developer storage container 26, a longitudinal end part is brought into a second state in which the longitudinal end part enters in the direction E in which the first frame body 17 is fitted to the second frame body 18, compared to a first state in which no external force is exerted.

Description

  The present invention relates to a developer storage unit that stores a developer, a developing device including the developer storage unit, a process cartridge, and an image forming apparatus.

  Here, the image forming apparatus forms an image on a recording medium using, for example, an electrophotographic image forming process, and includes an electrophotographic copying machine, an electrophotographic printer (such as an LED printer and a laser beam printer), an electrophotographic facsimile apparatus, and the like. Is included.

  The process cartridge is a cartridge in which at least an image carrier, a developer carrier, and a developer storage unit are integrally formed, and the cartridge can be attached to and detached from the image forming apparatus. It has been tied together.

  The developer storage unit is stored in the image forming apparatus or the process cartridge. The developer storage unit includes at least a flexible container for storing the developer.

  A conventional image forming apparatus using an electrophotographic forming process employs a cartridge system in which consumables are made into a cartridge and the cartridge can be attached to and detached from the image forming apparatus. As this cartridge, for example, a process cartridge in which an electrophotographic photosensitive member and process means acting thereon are integrated into a cartridge, a developer storage unit that stores a developer, and the like are known.

  In such a cartridge, as shown in FIG. 9, the opening provided in the developer storage frame 31 for storing the developer (toner, carrier, etc.) is sealed with a toner seal 32 as a sealing member. In use, a system is widely adopted in which the opening is opened by peeling the joint portion 33 of the toner seal 32 and the developer can be supplied.

  In addition, a developer storage container that can be deformed to solve the problem of the developer scattering in the cartridge machine during the developer filling process at the time of cartridge manufacture is used. The thing accommodated in the is proposed (patent document 1).

Japanese Patent Laid-Open No. 4-66980

  However, in order to extend the life of the cartridge without increasing the size of the image forming apparatus, a larger amount of developer storage container is stored in the developer storage container and a larger developer storage container than the frame forming the cartridge. It can be considered to be crushed and stored. In this case, the frame body may be deformed by the repulsive force of the deformable developer storage container. Further, when the frame is deformed, the positions of members such as the developer carrying member and the developing blade supported by the frame may change, and the image quality may be deteriorated.

  Accordingly, an object of the present invention is to provide a developer storage unit or the like having a long life without enlarging the image forming apparatus.

  To achieve the above object, the present invention provides a developer storage unit for storing a developer, having an opening for discharging the developer, and a flexible container for storing the developer, In a space that has a sealing member that seals the opening of the opening, a first frame, and a second frame, and is formed by assembling the first frame to the second frame And a frame for storing the developer discharged from the opened opening of the flexible container, the flexible container having an end portion in the long side direction having an external force Compared to the first state in which no is added, the second state in which the first frame body is inserted in the assembly direction of the first frame body can be taken.

  According to the present invention, it is possible to provide a long-life developer storage unit, a developing device, a process cartridge, and an image forming apparatus without increasing the size of the frame. Further, by reducing the deformation of the frame due to the repulsive force of the deformable flexible container, it is possible to prevent the image quality from being deteriorated due to the deformation of the frame.

It is sectional drawing explaining the assembly process to the 1st frame of a developing agent storage container, and a 2nd frame. It is a main sectional view of a process cartridge. 1 is a main cross-sectional view of an image forming apparatus. It is explanatory drawing explaining the structure of a developing agent storage unit. It is a perspective view explaining the structure of a developer storage container. It is explanatory drawing explaining the structure of a developer storage container. It is sectional drawing explaining the assembly process to the 1st frame of a developing agent storage container, and a 2nd frame. It is sectional drawing explaining the assembly process to the 1st frame of a developing agent storage container, and a 2nd frame. It is a perspective view of the conventional developer storage container. It is explanatory drawing explaining the structure of a developer storage container. It is explanatory drawing explaining the structure of a developing agent storage unit. It is sectional drawing explaining the assembly process to the 1st frame of a developing agent storage container, and a 2nd frame. It is sectional drawing explaining the assembly process to the 1st frame of a developing agent storage container, and a 2nd frame.

  Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the drawings. However, the dimensions, materials, shapes, functions, and relative arrangements of the components described in the embodiments described below should be changed as appropriate according to the configuration of the apparatus to which the present invention is applied and various conditions. It is. Therefore, unless specifically stated otherwise, the scope of the present invention is not intended to be limited thereto. Further, the materials, shapes, etc. of the members once described in the following description are the same as those in the first description unless otherwise described.

[Example 1]
Hereinafter, a process cartridge and an image forming apparatus having a developer storage unit according to the first exemplary embodiment will be described with reference to the drawings. In the following description, as shown in FIG. 4B, the longitudinal direction F is the direction of the long side of the box-shaped developer storage unit 25 or the developing device 38 (hereinafter referred to as the long side direction). Match.

  FIG. 2 is a main sectional view of a process cartridge to which the present invention can be applied, and FIG. 3 is a main sectional view of an image forming apparatus to which the present invention can be applied.

<Outline of process cartridge configuration>
As shown in FIG. 2, the process cartridge A includes a photosensitive drum 11 as an image carrier and process means that acts on the photosensitive drum 11. Examples of the process means include a charging means for charging the surface of the photosensitive drum 11 and a developing device (developing means) 38 for forming an image on the photosensitive drum 11. There is also a cleaning means for removing the developer T (including toner, carrier, etc.) remaining on the surface of the photosensitive drum 11.

  The process cartridge A according to the present embodiment is integrally provided with a cleaner unit 24 and a developing device 38 as shown in FIG. 2, and is detachable from the image forming apparatus B as shown in FIG. The cleaner unit 24 includes the photosensitive drum 11, and further includes a charging roller 12 as a charging unit and a cleaning blade 14 having elasticity as a cleaning unit around the photosensitive drum 11. Further, the developing device 38 as a developing unit includes a frame 40 composed of the first frame 17 and the second frame 18. The developing device 38 includes a developing roller 13 as a developer carrying member, a developing blade 15, a developer supply roller 23, and a developer storage unit 25 described later. The developing roller 13 and the developing blade 15 are supported by the first frame 17.

<Outline of configuration of image forming apparatus>
The process cartridge A is mounted on an image forming apparatus B as shown in FIG. 3 and used for image formation. In image formation, a sheet (recording medium) S is conveyed from a sheet cassette 6 mounted at the lower part of the image forming apparatus by a conveying roller 7 constituting a conveying unit, and in synchronization with this sheet conveyance, an exposure device 8 is provided on the photosensitive drum 11. A latent image is formed by selective exposure. The developer T is supplied to the developing roller 13 (developer carrier) by a sponge-like developer supply roller 23 and is carried on the surface of the developing roller 13 by a developing blade 15. By applying a developing bias to the developing roller 13, a developer T is supplied in accordance with the latent image to develop the developer image. This image is transferred to the conveyed sheet S by applying a bias voltage to the transfer roller 9. The sheet S is conveyed to the fixing device 10 to fix the image, and is discharged by the discharge roller 1 to the discharge unit 3 at the upper part of the image forming apparatus.

<Configuration outline of developer storage unit>
Next, the configuration of the developer storage unit 25 will be described with reference to FIG. As shown in FIG. 2, the developer storage unit 25 includes a developer storage container 26, a developing roller 13, a developing blade 15, and a first frame 17 and a second frame 18 that support them. . A combination of the first frame 17 and the second frame 18 is a frame 40 for storing the developer storage container 26. The developer storage container 26 includes a developer storage member 34 and a sealing member 19 as a flexible container for storing the developer T. The developer storage container 26 is stored in a space formed by assembling the first frame 17 to the second frame 18.

  In this embodiment, the developer storage unit 25 is the same as the developing device 38. This is because the developer storage unit 25 has the developing roller 13 and the developing blade 15. However, the developing roller 13 and the developing blade 15 may be supported by a separate frame from the developer storage unit 25 and separated from the developer storage unit 25. In this case, the developing device 38 includes the developer storage unit 25, the developing roller 13, and the developing blade 15 (not shown).

<Configuration outline of developer container>
Next, the configuration of the developer container 26 will be described with reference to FIGS. 4, 5, and 6. Here, FIG. 4A is a cross-sectional view before the sealing member 19 is peeled off from the developer storage container 26 of the developer storage unit 25. FIG. 4B is a perspective view of the developer storage unit 25. FIG. 5 is a cut perspective view of the developer storage container 26. FIG. 6A is a perspective view of the developer storage container 26. FIG. 6B is a cross-sectional view taken along line XX in FIG.

  As shown in FIGS. 4 and 5, the developer storage container 26 includes a developer storage member 34 as a flexible container and a sealing member 19, and can store the developer T therein. The developer accommodating member 34 includes a molded part 34a formed by injection molding, a sheet-like material in a concave shape by vacuum forming, pressure forming, or press molding, and a sheet-like air-permeable part 34b. Here, as a method of joining the molding portion 34a and the ventilation portion 34b, there are thermal welding, laser welding, adhesive, adhesive tape, and the like.

  Further, the air permeability of the ventilation portion 34b may be appropriately selected so that the developer T does not leak out of the developer storage container 26 in consideration of the size of the developer T to be stored (particle size of the powder). The material of the ventilation part 34b is polyethylene terephthalate (PET), polyethylene (PE), polypropylene (PP) or the like, and a non-woven fabric having a thickness of 0.03 to 0.25 mm is preferable. Note that the material of the ventilation portion 34b may not be a non-woven fabric, but may be one having finer holes than the powder of developer or the like stored in the developer storage container 26.

  A part of the outer peripheral portion 34c of the developer storage member 34 is provided with a hole 34g which is a fixed portion of the developer storage member 34 with respect to the second frame 18. Further, the second frame 18 is provided with a boss 18b which is a fixing portion for fixing the developer accommodating member 34. The developer storage container 26 is positioned with respect to the second frame 18 by engaging the hole 34 g of the developer storage member 34 with the boss 18 b of the second frame 18. Thereafter, the developer container 26 is fixed to the second frame 18 by melting the boss 18b by ultrasonic caulking. As means for fixing, in addition to ultrasonic caulking, other than ultrasonic waves can be used. For example, heat caulking using heat, adhesion using a solvent or an adhesive, sandwiching between frames, hooking by a hole and a convex part (boss, etc.), etc. may be used.

  A method for assembling the first frame 17 to the second frame 18 will be described later.

  The developer storage member 34 is provided with a discharge portion 35 as an opening for discharging the developer T. In order to prevent the developer T from leaking from the developer accommodating member 34 of the process cartridge A before use, the sealing member 19 is joined to the developer accommodating member 34 so as to cover the discharge portion 35. The sealing member 19 is a flexible sheet-like member for sealing the discharge portion 35. When the sealing member 19 is peeled off from the developer storage member 34, the discharge portion 35 is exposed, and the developer T can be discharged from the developer storage member 34. Here, a plurality of holes 34g and bosses 18b are provided in parallel with the longitudinal direction (long side direction) F of the developer accommodating member 34, and receive force when the sealing member 19 is opened from the developer accommodating member 34. ing.

  The sealing member 19 is connected to the opening member 20 by the engaged portion 19b, and the opening member 20 is rotatably supported by the second frame body 18. The unsealing member 20 is rotated in the direction of arrow C by driving force transmitted by a driving means (not shown) provided in the image forming apparatus B, thereby winding the sealing member 19 and exposing the discharge portion 35. Is possible. In addition, although the structure which opens the sealing member 19 automatically is illustrated here, it is not limited to this, For example, it is a structure opened manually, such as extracting and opening a sealing member to a longitudinal direction. There may be.

  Here, it is preferable that the discharge unit 35 is configured to easily discharge the developer T stored in the posture at the time of image formation. Therefore, in this embodiment, the discharge unit 35 is arranged so as to face vertically downward in the posture at the time of image formation.

  Next, the configuration of the developer container 26 will be described in detail with reference to FIG. FIG. 6A is a perspective view of the developer storage container 26. FIG. 6B is a cross-sectional view taken along line XX in FIG.

  As shown in FIGS. 6A and 6B, the top surface (upward in FIG. 6) of the developer storage container 26 is an end surface 26a, an end surface 26b, and a long side at the end in the long side direction. It consists of three surfaces, a central surface 26c at the center in the direction. In an assembly direction E of a first frame (not shown) to be described later, an end surface 26a, an end surface 26b from a surface 26h that is a surface facing the second frame (not shown) of the developer container 26. The distances to the central surface 26c are L1, L2, and L3, respectively. Then, L3 <L1 and L3 <L2.

  That is, the distances L1 and L2 of the widest portion between the surface facing the first frame 17 and the surface facing the second frame 18 in the assembly direction of the end portion in the long side direction of the developer container 26 are is there. Further, there is a widest distance L3 between the surface facing the first frame 17 and the surface facing the second frame 18 in the assembling direction of the central portion in the long side direction of the developer storage container 26. In this case, L1 and L2 are larger than L3.

  Further, the thickness t1 of the end face 26d and the thickness t2 of the end face 26e in the longitudinal direction (long side direction) F of the developer container 26 are the thickness t3 of the end face 26a provided in the direction crossing the assembly direction, and the end. It is thinner than the thickness t4 of the part surface 26b and the thickness t5 of the central part surface 26c. That is, t1, t2 <t3, t4, t5.

  Further, the end surface 26d and the end surface 26e of the developer storage container 26 are inclined by an angle θ1 and an angle θ2, respectively, with respect to the assembly direction E of the first frame (not shown). Here, the angles θ1 and θ2 are 0 ° <θ1 <90 ° and 0 ° <θ2 <90 °, and in this embodiment, θ1 = 3 ° and θ2 = 3 °. This reason will be described later.

<Assembling method of developer container into frame>
Next, a method for assembling the developer container 26 to the frame 40 will be described with reference to FIG. FIG. 1 shows a process of assembling the developer storage container 26 into the frame 40 and is a cross-sectional view of the developer storage unit 25 cut in the longitudinal direction F. FIG. 1A is a cross-sectional view illustrating a state in which the developer storage container 26 is fixed to the second frame 18. FIG. 1B is a cross-sectional view illustrating a state in the middle of assembling the first frame 17 with respect to the second frame 18 to which the developer storage container 26 is fixed. FIG. 1C is a cross-sectional view illustrating a state after the first frame body 17 is assembled to the second frame body 18. Here, the developer container 26 in the first state before the first frame 17 is assembled to the second frame 18 is indicated by a two-dot chain line in the drawing.

  Note that the first state of the developer storage container 26 indicated by a two-dot chain line in FIG. 1C is a state in which an external force is not applied to the end portion in the long side direction. It can be said that it is a natural state where no external force is applied. On the other hand, the state of the developer container 26 indicated by the solid line in FIG. 1C is such that the end in the long side direction of the first frame 17 relative to the second frame 18 is larger than that in the first state. It is the 2nd state which has penetrate | invaded in the assembly | attachment direction E. FIG.

  As shown in FIG. 1A, the developer container 26 is positioned and fixed with respect to the second frame 18 by the method described above.

  Next, as shown in FIG. 1B, the first frame 17 is assembled in the assembling direction E with respect to the developer storage container 26 that is integrally fixed to the second frame 18. When assembled, first, the opposing surface 17a of the first frame 17 abuts the end surface 26a and the end surface 26b of the end in the long side direction of the developer container 26.

  Next, as shown by a two-dot chain line in FIG. 1C, FIG. 1C is a state in which the first frame 17 is assembled at a predetermined position with respect to the second frame 18. . The end surface 26a and the end surface 26b of the developer container 26 are assembled in the assembly direction E with respect to the opposing surface 17a of the first frame body 17 as compared to the first state where no external force is applied. It will be in the second state that has entered.

  That is, when the first frame 17 is moved in the assembling direction E from FIG. 1B, the developer container 26 is flexible, and therefore the end surface 26a of the developer container 26, the end The part surface 26 b is crushed in the assembly direction E by the opposing surface 17 a of the first frame body 17. At this time, when the inside of the developer storage container 26 is filled with the developer T and air, the air inside the developer storage container 26 exits from the vent 34b, so that the developer storage container 26 is crushed. . Further, when the inside of the developer storage container 26 is filled only with the developer T, the side face 26d and the side face 26e, which are end faces in the long side direction of the developer storage container 26, are bent outward in the longitudinal direction F. The developer T moves outward in the longitudinal direction F, and the developer container 26 is crushed. Details will be described later.

  Here, the end surface 26a1 and the end surface 26b1 of the developer storage container 26 in the second state that are crushed by the surface 17a and stored in the frame 40 are shown by solid lines in FIG. At this time, a distance L1 from the surface 26h to the end surface 26a in the first state, and a distance L2 from the surface 26h to the end surface 26b in the first state. And it is set as the distance L54 between the surface 18a of the 2nd frame 18 which opposes the surface 26h, and the surface 17a of the 1st frame 17 which opposes the edge part surface 26a and the edge part surface 26b. In this case, L1 and L2 are larger than L54. That is, L54 <L1 and L54 <L2. Further, the distance L3 from the surface 26h to the central portion surface 26c is smaller than or equal to the distance L54. That is, L3 ≦ L54.

  Therefore, the frame 40 formed by the first frame 17 and the second frame 18 has a reaction force P1 and a reaction force caused by crushing the developer storage container 26 at the end surface 40a and the end surface 40b. Receive P2. The reaction force P1 and the reaction force P2 are the resultant of the following three forces. The first force is a force P1A or P2A for deforming the developer container 26 having flexibility. The second force is forces P1B and P2B that allow the air inside the developer container 26 to escape from the ventilation portion 34b when the developer container 26 is crushed by the frame 40. The third force is forces P1C and P2C that push away the developer T inside the developer container 26. The deforming forces P1A and P2A, the escaping forces P1B and P2B, and the retreating forces P1C and P2C are shown in only one direction in the figure, but the developer container 26 is flexible and is in the opposite direction of the arrow. Also power is applied.

  Here, the frame body 40 has a box shape that is long in the longitudinal direction (long side direction) F as shown in FIG. For this reason, as shown in FIG. 1, the end surface 40a and the end surface 40b are connected to an end surface 40d and an end surface 40e formed substantially parallel to the assembly direction E. Therefore, the rigidity with respect to the assembly direction E of the end surface 40a and the end surface 40b is higher than the rigidity with respect to the assembly direction E of the center surface 40c. Therefore, in the long side direction, the reaction force of the developer container 26 is not applied to the central portion surface 40c of the frame body 40 having low rigidity, and the developer is formed by the end surfaces 40a and 40b of the frame body 40 having high rigidity. By receiving the reaction force P1 and reaction force P2 of the storage container 26, the deformation of the frame body 40 can be reduced.

  Further, as described above, the thickness t1 of the end surface 26d of the developer storage container 26 and the thickness t2 of the end surface 26e are the thicknesses of the end surface 26a of the developer storage container 26 provided in a direction crossing the assembly direction. It is thinner than t3, thickness t4 of the end face 26b, and thickness t5 of the central face 26c. Therefore, the end surface 26d and the end surface 26e of the developer storage container 26 are easily buckled and deformed in the assembly direction E, and the forces P1A and P2A for deforming the developer storage container 26 are reduced. Accordingly, the reaction force P1 and the reaction force P2 are smaller than when the entire developer storage container 26 is formed with a uniform thickness.

  Here, when the developer container 26 is assembled to the frame 40 or when the developer container 26 is filled with the developer T, the developer container 26 is maintained in order to maintain the shape of the developer container 26. Requires a certain thickness. However, since the surface areas of the end surface 26d and the end surface 26e are smaller than the entire surface area of the developer storage container 26, the influence on the maintenance of the shape of the developer storage container 26 is small. Therefore, it is possible to reduce the thickness of the end surface 26d and the end surface 26e.

  Further, as described above, the end surface 26d and the end surface 26e of the developer container 26 are inclined by the angles θ1 and θ2 with respect to the assembly direction E of the first frame 17 and the second frame 18. . Therefore, the forces P1A and P2A for deforming the developer container 26 act as a component force P1D = P1Acosθ1 and a component force P2D = P2Acosθ2 with respect to the assembly direction E in which the reaction force P1 and the reaction force P2 are generated. Accordingly, the reaction force P1 and the reaction force P2 are smaller than when the end face 26d and the end face 26e are formed in parallel to the assembly direction E.

  A gap L6 and a gap in the longitudinal direction F are provided between the end face 26d of the developer container 26 and the end face 40d of the frame body 40, and between the end face 26e of the developer container 26 and the end face 40e of the frame body 40, respectively. L7 is provided. Therefore, the developer T that moves when the end surface 26a and the end surface 26b are crushed is accommodated in the convex portions 26d1 and 26e1 due to the deflection of the side surfaces 26d and 26e generated by the end surface 26a and 26b being crushed. Is possible. Here, the convex portion 26d1 and the convex portion 26e1 of the developer storage container 26 stored between the first frame body 17 and the second frame body 18 are indicated by solid lines in FIG.

  With the above configuration, even when the developer storage container 26 whose long side end is intruding into the frame body 40 is stored, the frame body 40 due to the reaction force P1 and reaction force P2 of the developer storage container 26 is stored. Deformation can be reduced. Therefore, it is possible to provide a developing device 38 that reduces the change in the position of the process means such as the developing roller 13 attached to the frame body 40 and has good image quality. Further, it is possible to provide the long-life developer storage unit 25, the developing device 38, the process cartridge A, and the image forming apparatus B without increasing the size of the frame body 40 and thus without increasing the size of the image forming apparatus B. .

  The end face 26a, the thickness t6 of the inclined face 26f between the end face 26b and the central face 26c, and the thickness t7 of the inclined face 26g are the thickness t3 of the end face 26a and the thickness of the end face 26b. It is desirable that the thickness is smaller than t4 and the thickness t5 of the central portion surface 26c. As a result, the developer container 26 is likely to buckle and deform in the assembling direction E, and the forces P1A and P2A that deform the developer container 26 are reduced.

  The inclined portion surface 26f and the inclined portion surface 26g are inclined with respect to the assembly direction E of the first frame (not shown) and the second frame (not shown) (for example, the angle θ3 and the angle θ4 shown in FIG. 1). ) Is preferable. As a result, the forces P1A and P2A for deforming the developer container 26 act as a component force P1D = P1Acosθ3 and a component force P2D = P2Acosθ4 with respect to the assembly direction E in which the reaction forces P1 and P2 are generated. Accordingly, the reaction force P1 and the reaction force P2 are smaller than when the inclined portion surface 26f and the inclined portion surface 26g are formed in parallel to the assembly direction E.

  In the present embodiment, the suppression of the deformation of the frame body 40 by the reaction force P1 and the reaction force P2 when the first frame body 17 is assembled to the second frame body 18 has been described. However, when the first frame 17 is assembled to the second frame 18, the flexible developer storage container 26 is crushed so as to be smaller than the frame 40 (second state). Even when the first frame 17 is assembled to the second frame 18, the same effect can be obtained. Even if the developer container 26 is crushed so as to be smaller than the frame body 40 in advance, the developer container is stored from the ventilation portion 34b after the first frame body 17 is assembled to the second frame body 18. Air flows into the container 26. This is because the inflow causes a restoring force to return the developer container 26 to its original shape. Therefore, even when the first frame 17 is assembled to the second frame 18 in a state where the flexible developer storage container 26 is crushed to be smaller than the frame 40 in advance, the first frame The reaction force P1 and reaction force P2 of the developer container 26 are applied to the 17 and the second frame 18.

  The direction in which the developer container 26 is crushed may be any direction as long as it is substantially the same as the direction in which the first frame 17 is assembled to the second frame 18.

  In the present embodiment, the example in which the end face 26d and the end face 26e of the developer container 26 are deformed when the first frame 17 is assembled to the second frame 18 has been described. However, when the first frame 17 is assembled to the second frame 18 as shown in FIG. 10, in addition to the deformation of the end face 26d and the end face 26e described above, the short of the developer container 26 is short. The end face 26k in the hand direction G can be deformed simultaneously. The deformation of the end face 26k in the short direction G will be specifically described in an embodiment described later. FIGS. 10A and 10B are perspective views for explaining a state where the developer storage container 26 is deformed. FIG. 10 shows a state in which the end face 26k in the short direction G, the end face 26d in the longitudinal direction F, and the end face 26e are simultaneously deformed. By simultaneously deforming in this way, it is possible to store in one of various forms of frames as compared with the case of deforming either one.

[Example 2]
Next, a process cartridge and an image forming apparatus having a developer storage unit according to the second embodiment will be described with reference to FIG. In the present embodiment, a configuration different from the above-described embodiment will be described, and members having similar configurations and functions are denoted by the same reference numerals and the previous embodiment is used.

  FIG. 7 shows a process of assembling the developer storage container 126 into the frame 140 in this embodiment, and is a cross-sectional view of the developer storage unit 125 cut in the longitudinal direction F. FIG. FIG. 7A is a cross-sectional view illustrating a state in which the developer storage container 126 is fixed to the second frame 118. FIG. 7B is a cross-sectional view illustrating a state in the middle of assembling the first frame 117 to the second frame 118 to which the developer storage container 126 is fixed. FIG. 7C is a cross-sectional view illustrating a state after the first frame body 117 is assembled to the second frame body 118. Here, the developer storage container 126 in the first state before the first frame 117 is assembled to the second frame 118 is indicated by a two-dot chain line in the drawing.

  Note that the first state of the developer storage container 126 indicated by a two-dot chain line in FIG. 7C is a state in which an external force is not applied to the end portion in the long side direction. On the other hand, the state of the developer container 126 indicated by the solid line in FIG. 7C is such that the end in the long side direction of the first frame body 117 with respect to the second frame body 118 is larger than that in the first state. It is the 2nd state which has penetrate | invaded in the assembly | attachment direction E. FIG.

  As shown in FIG. 7 (a), the developer accommodating member 134 in this embodiment includes a first molding portion 134a formed by injection molding, vacuum molding, pressure molding, press molding of a sheet-like material, and second molding. Part 134b. That is, in Example 1, the developer accommodating member 34 is configured by the molding portion 34a and the ventilation portion 34b, but in this embodiment, the developer storage member 34 is configured by the second molding portion 134b that does not vent instead of the ventilation portion 34b. Therefore, the developer storage member 134 does not allow air to pass from the inside to the outside. Here, as a method of joining the first molding part 134a and the second molding part 134b, there are thermal welding, laser welding, adhesive, adhesive tape, and the like.

  The fixing method of the developer container 126 to the second frame 118 is the same as in the first embodiment.

  Next, as shown in FIG. 7B, when the first frame body 117 is assembled to the developer storage container 126 that is integrally fixed to the second frame body 118, first, the developer storage container. The end surface 126 a and the end surface 126 b of the 126 abut against the opposing surface 117 a of the first frame body 117.

  Next, as shown by a two-dot chain line in FIG. 7C, the first frame 117 is in a state assembled at a predetermined position of the second frame 128. In this case, the developer storage container 126 has an end surface 126a and an end surface 126b that are opposed to the opposing surface 117a of the first frame 117 as compared to the first state in which no external force is applied. Intrusion direction E.

  That is, the first frame 117 is moved in the assembling direction E from FIG. When the developer storage container 126 moves, the end surface 126a, 126b is crushed in the assembling direction E by the opposing surface 117a of the first frame 117. At this time, the end surface 126d and end surface 126e in the long side direction of the developer storage container 126 are bent outward in the longitudinal direction F, whereby the developer storage container 126 is crushed. Details will be described later.

  Here, the end surface 126a1 and the end surface 126b1 of the developer storage container 126 in the second state that are crushed by the surface 117a and stored in the frame 140 are indicated by solid lines. At this time, a distance L11 from the surface 126h to the end surface 126a and a distance L12 from the surface 126h to the end surface 126b are used. Further, assuming that the distance L14 between the surface 118a of the second frame 118 facing the surface 126h and the surface 117a of the first frame 117 facing the end surface 126a and the end surface 126b is L11 and L12. Is greater than L14. That is, L14 <L11 and L14 <L12. Further, the distance L13 from the surface 126h to the central portion surface 126c is smaller than or equal to the distance L14. That is, L13 ≦ L14.

  Therefore, the frame 140 formed by the first frame 117 and the second frame 118 has a reaction force P11 and a reaction force caused by crushing the developer storage container 126 at the end surface 140a and the end surface 140b. Receive P12. The reaction force P11 and the reaction force P12 are the resultant force P11A, P12A for deforming the flexible developer storage container 126, and the resultant force P11C, P12C for pushing away the developer T inside the developer storage container 126.

  Here, the frame 140 has a box-like shape that is long in the longitudinal direction (long side direction) F as shown in FIG. For this reason, as shown in FIG. 7, the end surface 140a and the end surface 140b are connected to an end surface 140d and an end surface 140e formed substantially parallel to the assembly direction E. Therefore, the rigidity with respect to the assembly direction E of the end surface 140a and the end surface 140b is higher than the rigidity with respect to the assembly direction E of the center surface 140c. Therefore, in the long side direction, the reaction force of the developer container 126 is not applied to the central part surface 140c of the frame body 140 having low rigidity. The deformation of the frame 140 can be reduced by receiving the reaction force P11 and reaction force P12 of the developer storage container 126 at the end surface 140a and the end surface 140b having high rigidity of the frame 140.

  Further, as described above, the thickness t11 of the end surface 126d and the thickness t12 of the end surface 126e of the developer storage container 126 are the thickness t13 and the end surface 126b of the end surface 126a provided in the direction intersecting the assembly direction. Thickness t14 and the thickness t15 of the central portion surface 126c. Therefore, the end surface 126d and the end surface 126e of the developer storage container 126 are easily buckled and deformed in the assembly direction E, and the force for deforming the developer storage container 126 is reduced. Accordingly, the reaction force P11 and the reaction force P12 are smaller than when the entire developer storage container 26 is formed with a uniform thickness.

  A gap L16 and a gap in the longitudinal direction F are provided between the end face 126d of the developer container 126 and the end face 140d of the frame 140, and between the end face 126e of the developer container 126 and the end face 140e of the frame 140, respectively. L17 is provided. As described above, since the developer container 126 does not allow air to pass from the inside to the outside, the volume inside the developer container 126 does not change when the developer container 126 is crushed by the frame 140. Therefore, the volume of the developer storage container 126 that decreases due to the difference between the height L11 and the height L12 and the height L14 is such that the protrusion 126d1 of the developer storage container 126 expands into the gap L16 and the protrusion 126e1 expands into the gap L17. Supplemented with Further, depending on the amount of movement of the developer T, the convex portion 126d1 of the developer storage container 126 swells into the gap L16, and the convex portion 126e1 swells into the gap L17. As a result, the developer storage container 126 formed larger than the frame body 140 can be stored between the first frame body 117 and the second frame body 118. Here, the convex portion 126d1 and the convex portion 126e1 of the developer storage container 126 stored between the first frame body 117 and the second frame body 118 are shown by solid lines in FIG.

  With the above configuration, even when the developer storage container 126 whose long side end is intruding into the frame 140 is stored, the frame 140 due to the reaction force P11 and reaction force P12 of the developer storage container 126 is stored. Deformation can be reduced. For this reason, it is possible to provide a developing device 138 that reduces the change in position of the process means such as the developing roller 13 attached to the frame 140 and has good image quality. Further, it is possible to provide a long-life developer storage unit 125, a developing device 138, and the like without increasing the size of the frame 140.

Example 3
Next, a process cartridge and an image forming apparatus having a developer storage unit according to the third embodiment will be described with reference to FIG. In the present embodiment, a configuration different from the above-described embodiment will be described, and members having similar configurations and functions are denoted by the same reference numerals and the previous embodiment is used.

  FIG. 8 shows a process of assembling the developer container 226 into the frame 240 in this embodiment, and is a cross-sectional view of the developer container unit 225 cut in the longitudinal direction F. FIG. 8A is a cross-sectional view illustrating a state in which the developer storage container 226 is fixed to the second frame 218. FIG. 8B is a cross-sectional view illustrating a state in the middle of assembling the first frame 217 with respect to the second frame 218 to which the developer storage container 226 is fixed. FIG. 8C is a cross-sectional view illustrating a state after the first frame 217 is assembled to the second frame 218. Here, the developer container 226 in the first state before the first frame 217 is assembled to the second frame 218 is indicated by a two-dot chain line in the drawing.

  Note that the first state of the developer container 226 indicated by a two-dot chain line in FIG. 8C is a state in which an external force is not applied to the end portion in the long side direction. On the other hand, the state of the developer container 226 indicated by the solid line in FIG. 8C is such that the end in the long side direction of the first frame 217 with respect to the second frame 218 is larger than that in the first state. It is the 2nd state which has penetrate | invaded in the assembly | attachment direction E. FIG.

  As shown in FIG. 8A, the developer accommodating member 234 in this embodiment includes a molding part 234a and a ventilation part 234b. The method for fixing the developer container 226 to the second frame 118 is the same as in the first embodiment.

  Next, as shown in FIG. 8B, the first frame 217 is assembled to the developer storage container 226 that is integrally fixed to the second frame 218. Then, the surface 226a of the developer container 226 first comes into contact with the end surface 217a and the end surface 217b in the longitudinal direction F of the first frame 217 facing each other.

  Next, as shown by a two-dot chain line in FIG. 8C, FIG. 8C shows a state in which the first frame 217 is assembled to the second frame 218 at a predetermined position. In this case, both ends of the developer container 226 in the longitudinal direction F are assembled to the end surfaces 217a and 217b of the first frame body 217 facing each other as compared with the first state where no external force is applied. The second state enters the direction E.

  That is, when the first frame 217 is moved in the assembling direction E from FIG. 8B, the developer container 226 has flexibility, so that both end portions in the longitudinal direction F are opposed to each other. The frame 217 is crushed in the assembly direction E by the end surfaces 217a and 217b. At this time, when the inside of the developer storage container 226 is filled with the developer T and air, the air inside the developer storage container 226 exits from the ventilation portion 234b, so that the developer storage container 226 is crushed. . Further, when the inside of the developer storage container 226 is filled only with the developer T, the side surface 226d and the side surface 226e which are end surfaces in the long side direction of the developer storage container 226 are bent outward in the longitudinal direction F. The developer T moves outward in the longitudinal direction F, and the developer storage container 226 is crushed.

  Here, a surface 226a1 of the developer container 226 that is crushed by the end surface 217a and the end surface 217b is shown by a solid line in FIG. At this time, the distance L21 from the surface 226h to the surface 226a is such that the surface 218a of the second frame 218 facing the surface 226h, the end surface 217a of the first frame 217 facing the surface 226a, and the end surface. It is larger than the distances L22 and L23 between 217b. That is, L22 <L21 and L23 <L21. Further, the distance L24 from the surface 218a to the central portion surface 217c is greater than or equal to the distance L21. That is, L21 ≦ L24.

  Therefore, the frame 240 formed by the first frame 217 and the second frame 218 has a reaction force P21 and a reaction force caused by crushing the developer storage container 226 at the end surface 240a and the end surface 240b. Receive P22. Here, the frame 240 has a box-like shape that is long in the longitudinal direction F as shown in FIG. 4B, and the end surface 240 a and the end surface 240 b are formed substantially parallel to the assembly direction E. The end surface 240d is connected to the end surface 240e. Therefore, the rigidity with respect to the assembly direction E of the end surface 240a and the end surface 240b is higher than the rigidity with respect to the assembly direction E of the central surface 240c. Therefore, in the long side direction, the reaction force of the developer storage container 226 is not applied to the central portion surface 240c having a low rigidity of the frame body 240. On the other hand, the deformation of the frame 240 can be reduced by receiving the reaction force P21 and reaction force P22 of the developer container 226 on the end surface 240a and the end surface 240b having high rigidity of the frame 240.

  With the above configuration, even when the developer storage container 226 whose long side end is intruding into the frame 240 is stored, the reaction body P <b> 21 and the reaction force P <b> 22 of the developer storage container 226 cause the frame 240 to move. Deformation can be reduced. For this reason, it is possible to provide a developing device 238 that reduces the change in position of the process means such as the developing roller 13 attached to the frame 240 and has good image quality. Further, it is possible to provide the developer storage unit 225 and the developing device 238 having a long lifetime without increasing the size of the frame 240.

  In the above-described embodiment, the process cartridge that is detachable from the image forming apparatus is a process that integrally includes a photosensitive drum and a charging unit, a developing unit, and a cleaning unit as a process unit that acts on the photosensitive drum. A cartridge was illustrated. However, the process cartridge is not limited to this, and may be a cartridge integrally including a developer carrying member and a developer unit in addition to the photosensitive drum. In addition, a process cartridge that integrally includes one of a charging unit and a cleaning unit may be used.

Example 4
A mode in which the end surface in the short-side direction G of the developer container 26 described at the end of the first embodiment is deformed will be specifically described.

(Relationship between developer container shape and frame shape)
The shape of the developer storage container 26 before being stored in the first frame 17 and the second frame 18, and the first frame 17 and the second frame 18 storing the developer storage container 26. The shape relationship of the combined frame 40 will be described.

  As shown in FIG. 11, the top surface 17 a (contact surface) of the first frame 17 and the top surface 34 k (third surface) of the developer storage member 34 are parallel to each other, and the first frame 17. A case where the top surface 17a is perpendicular to the assembly direction E of the second frame 18 will be described. Furthermore, the assembly direction E of the first frame body 17 and the second frame body 18 is such that the coupling surfaces 17b and 18c of the first frame body 17 and the second frame body 18 (see FIG. 12A). In contrast, the direction is orthogonal.

  As shown in FIG. 11, the developer container 26 has a frame body 40 in a direction (same direction as the assembly direction E) perpendicular to the coupling surfaces 17 b and 18 c of the first frame body 17 and the second frame body 18. (See the hatched portion J in FIG. 11).

  The details of the method of assembling the first frame 17 and the second frame 18 will be described in the method of assembling the developer container 26 to the frame 40 described later.

  Specifically, the width of the outer shape of the developer storage container 26 at an arbitrary position in the direction orthogonal to the coupling surfaces 17b and 18c is a length L121, and the distance between the inner walls of the frame 40 at a position corresponding to the length L121. Is a length L122, there is a relationship of length L121> length L122.

  Furthermore, the surface 34f (first surface) having the opening 35 of the developer storage member 34 and the surface 34j (second surface) opposite to the surface 34f are in relation to the top surface 34k so as to have the relationship shown below. The developer accommodating member 34 is formed by changing the angle between the surface 34f and the surface 34j. Here, the top surface 17a of the first frame 17 is a surface that first comes into contact with the developer storage member 34 during assembly.

  In the assembly direction E, the angle θ11 is greater than the angle θ12, where the angle θ11 is the inner angle between the top surface 17a and the surface 34f and the angle θ12 is the angle between the top surface 17a and the surface 34j.

(Assembling method of developer container into frame)
Next, a method for assembling the developer container 26 to the frame 40 will be described.

  FIG. 12 is a cross-sectional view sequentially illustrating a method of assembling the developer container 26 into the frame body 40. 12A is a cross-sectional view in which the developer storage container 26 is fixed to the second frame 18, and FIG. 12B is a first view of the second frame 18 to which the developer storage container 26 is fixed. It is sectional drawing of the process of assembling the frame 17 of this. Further, in FIG. 12C, the second frame 18 and the first frame 17 are combined to form a frame 40, and the developer is accommodated between the second frame 18 and the first frame 17. It is sectional drawing showing the state in which the container 26 was accommodated.

[Fixing the developer container to the second frame]
First, as shown in FIG. 12A, the developer storage container 26 is engaged with the second frame 18 by engaging the hole 34 h of the developer storage member 34 and the boss 18 b of the second frame 18. Fixed. In the present embodiment, the engagement is performed by ultrasonic caulking, but the fixing means may be other than ultrasonic caulking as long as the developer accommodating member 34 can be fixed to the second frame 18. For example, heat caulking using heat, adhesion using a solvent or an adhesive, sandwiching between frames, hooking a hole on a convex portion such as a boss, and the like can be mentioned.

[Assembly of the first frame and the second frame]
Next, the first frame 17 is assembled in the direction E shown in FIG. 12B with respect to the second frame 18 to which the developer storage container 26 is fixed. At this time, the developer container 26 in the assembling direction E is larger than the frame body 40 constituted by the first frame body 17 and the second frame body 18 (see the hatched portion J in FIG. 11).

  Therefore, when the first frame body 17 is assembled, the top surface 17 a of the first frame body 17 first comes into contact with the top surface 34 k of the developer storage member 34. The top surface 34k is a surface that intersects both the surface 34f of the developer storage member 34 having the opening 35 and the surface 34j of the developer storage member 34 that faces the surface 34f. That is, the top surface 34 k of the developer storage member 34 is a contact portion with the top surface 17 a of the first frame 17.

  Since the developer storage container 26 has flexibility, the developer storage container 26 is crushed and deformed in the assembly direction E by the top surface 17a of the first frame 17. At this time, the internal air is degassed in the direction of arrow H in FIG. 12B from the vent 34b of the developer container 26, and the developer 39 inside the developer container 26 is compressed with high density. As a result, the developer storage container 26 that is formed larger than the frame body 40 is stored between the first frame body 17 and the second frame body 18.

  Here, the relationship between the surface 34f of the developer storage member 34 having the opening 35 and the force received by the top surface 17a of the first frame 17 on the surface 34j of the developer storage member 34 facing the surface 34f is shown below.

  As shown in FIG. 12B, when the top surface 17a of the first frame 17 and the top surface 34k of the developer storage member 34 are in contact with each other, a bent portion 34m that connects the top surface 34k and the surface 34j, A force in the direction of arrow F perpendicular to the top surface 17a acts on the bent portion 34n that connects the surface 34k and the surface 34f. Here, the bent portion 34 m and the bent portion 34 n are contact portions with the top surface 17 a of the first frame body 17. Therefore, the forces received by the surface 34f and the surface 34j of the developer storage member 34 can be expressed as follows using the angle θ11 and the angle θ12 described above.

[Force applied to the bent part]
The following forces are applied to the bent portion 34n.

  Force component in a direction parallel to the surface 34f having the opening 35: F1x

F1x = F × cos | θ11−90 ° |
Force component in the direction perpendicular to the surface 34f having the opening 35: F1y

F1y = F × sin | θ11−90 ° |
Force component in the direction parallel to the top surface 17a of the first frame 17: F1yy

F1yy = F × sin | θ11−90 ° | × cos | θ11−90 ° |
Here, sin θ × cos θ = (sin 2θ) / 2,

F1yy = F × (sin (2 × | θ11−90 ° |)) / 2
On the other hand, the following force is applied to the bent portion 34m.

  Force component in a direction parallel to the surface 34j: F2x

F2x = F × cos | θ12−90 ° |
Force component in the direction perpendicular to the surface 34j: F2y

F2y = F × sin | θ12−90 ° |
Force component in the direction parallel to the top surface 17a of the first frame 17: F2yy

F2yy = F × sin | θ12−90 ° | × cos | θ12−90 ° |
= F × (sin (2 × | θ12−90 ° |)) / 2

  Here, the force F1x is a force component that bends the surface 34j of the developer accommodating member 34 and the force F2x bends (creates wrinkles) the surface 34j of the developer accommodating member 34. The larger the force, the easier the surface bends. Is shown. Further, the force F1yy is a force component that tilts the surface 34f of the developer accommodating member 34, and the force F2yy is a force component that tilts the surface 34j of the developer accommodating member 34. The larger the force, the more easily the surface is tilted.

  Here, by satisfying the relationship of angle θ11> angle θ12,

Force F1x <force F2x, force F1yy> force F2yy
It becomes.

  For this reason, when crushed in the direction E by the top surface 17a of the first frame 17, the surface having the opening 35 rather than the surface 34f having the opening 35 of the developer accommodating member 34 due to the relationship of force F1x <force F2x. The surface 34j facing 34f is actively bent.

  Further, due to the relationship of force F1yy> force F2yy, the bent portion 34m and the bent portion 34n of the developer storage member 34 move in the direction of arrow Q. Then, the surface 34f having the opening 35 is positively tilted toward the inside of the developer accommodating member 34 (in the direction of arrow Q in FIG. 12B).

  Therefore, in the developer container 26, the bent portion 34n moves in the arrow Q direction, and the force F1x applied to the surface 34f having the opening 35 is released. As a result, the surface 34f can be stored between the first frame 17 and the second frame 18 while preventing bending and wrinkling.

  For this reason, it is possible to prevent the opening from being bent or wrinkled without providing a mechanism that spreads the opening with a leaf spring or the like in the vicinity of the opening, and it is possible to discharge the developer from the developer storage container at a low cost. It becomes possible.

  As described above, as shown in FIG. 12C, the developer storage container 26 is formed larger than the frame body 40, but is stored between the first frame body 17 and the second frame body 18. Therefore, the developer can be stored efficiently.

  The surface 34j of the developer storage container 26 is tilted to the outside of the developer storage container 26, and a part of the developer storage container 26 is stored in a space above the first frame 17 forming the frame 40. Is done.

  By preventing the surface 34f having the opening 35 from being bent or wrinkled, the opening 35 can be prevented from being deformed, and the developer 39 can be supplied stably.

  In the present embodiment, the description has been made as the developing device 38 in which the developing roller 13, the developing blade 15, and the developer storage container 26 are integrated into a unit, but the present invention is not necessarily limited thereto. For example, the developing device 38 having the developing roller 13, the developing blade 15 and the frame body 40 that holds the developing roller 13, and the developer storage unit having the developer storage container 26 may be attached as separate members. Good.

Example 5
This embodiment has a configuration different from that of the fourth embodiment with respect to the shape relationship between the developer container and the developing device.

  In the present embodiment, the top surface 17a of the first frame 17 and the top surface 34k of the developer storage member 34 in Embodiment 4 are not parallel and the top surface 17a is not perpendicular to the assembly direction E. The case will be described.

  In addition, the same code | symbol is attached | subjected about the part which is the same or similar to 1st Embodiment, and the overlapping description is abbreviate | omitted.

(Relationship between developer container shape and frame shape)
A developer storage container 126 is formed by combining the shape of the developer storage container 126 before being stored in the first frame 117 and the second frame 118 and the first frame 117 and the second frame 118. The shape relationship of the frame 140 to be stored will be described.

  FIG. 13 is a cross-sectional view sequentially illustrating a method of assembling the developer container 126 into the frame 140. FIG. 13A shows the shape of the developer storage container 126 before being stored in the first frame 117 and the second frame 118, and the first frame 117 and the second frame 118. It is sectional drawing showing the shape relationship of the frame 140 which match | combined. The assembly direction E of the first frame body 117 and the second frame body 118 is the same as that of the fourth embodiment, with respect to the coupling surfaces 117b and 118b between the first frame body 117 and the second frame body 118. The directions are orthogonal (see FIGS. 13A and 13B).

  As shown in FIG. 13A, the developer storage container 126 is similar to the first embodiment in the direction orthogonal to the coupling surfaces 117b and 118b of the first frame body 117 and the second frame body 118. It is larger than the frame 140.

  The details of the method for assembling the first frame 117 and the second frame 118 will be described in the method for assembling the developer container 126 to the frame 140 described later.

  Here, the width of the outer shape of the developer storage container 126 at an arbitrary position in the direction orthogonal to the coupling surfaces (117b, 118b) is defined as a length L53. The distance between the inner walls of the frame 140 at the position corresponding to the length L53 is defined as a length L54. The length L53> the length L54.

  Further, in the present embodiment, the top surface 117a (contact surface) of the first frame 117 that first comes into contact with the developer storage member 134 of the developer storage container 126 at the time of assembly is characterized so as to satisfy the following relationship. I'm giving it back.

  That is, if an internal angle formed by the top surface 117a of the first frame 117 and the surface 134f (first surface) having the opening 135 of the developer storage member 134 is an angle θ13, 90 ° <angle θ13 <180 ° The top surface 117a is inclined so as to be related. Further, when the first frame body 117 and the second frame body 118 are joined together, a space is provided in which the crushed developer storage container 126 is stored (FIG. 13A, hatched portion K). That is, the surface 134j (second surface) of the developer storage container 126 is tilted to the shaded portion K, and a part of the developer storage container 126 is stored in the space of the shaded portion K.

(Assembling method of developer container into frame)
Next, a method for assembling the developer container 126 into the frame will be described. FIG. 13B is a cross-sectional view illustrating a state in which the developer storage member 134 of the developer storage container 126 is crushed by the first frame body 117. In FIG. 13C, the second frame 118 and the first frame 117 are combined to form the frame 40, and the developer is accommodated between the second frame 118 and the first frame 117. It is sectional drawing showing the state in which the container 126 was accommodated.

[Assembly of the first frame and the second frame]
Next, the first frame 117 is assembled in the direction E shown in FIG. 13B with respect to the second frame 118 to which the developer storage container 126 is fixed. At this time, the developer storage container 126 in the assembly direction E is larger than the frame 140 configured by the first frame 117 and the second frame 118 (see the hatched portion J in FIG. 13A). .

  Therefore, when the first frame body 117 is assembled, the top surface 117a of the first frame body 117 first comes into contact with the bent portion 134n. That is, the bent portion 134 n of the developer storage member 134 is a contact portion with the top surface 117 a of the first frame body 117.

  As shown in FIG. 13B, when the top surface 117a of the first frame 117 is in contact with the bent portion 134n of the developer storage member 134, the top surface 117a of the first frame 117 and the developer storage member The top surface 134k of 134 has the following relationship. That is, the angle formed between the top surface 117a and the surface 134f of the first frame 117 on the developer storage container 26 side is larger than the angle formed between the top surface 134k and the surface 134f on the inner side of the developer storage container 26. It's getting bigger.

  Since the developer storage container 126 has flexibility, the developer storage container 126 is crushed and deformed in the assembly direction E by the top surface 117a of the first frame body 117. At this time, as in the first embodiment, the developer storage container 126 is evacuated from the ventilation portion 116 in the direction of arrow H in FIG. 13B, and the developer 39 inside the developer storage container 126 is high. Compressed to density. As a result, the developer storage container 126 formed larger than the frame body 140 can be stored between the first frame body 117 and the second frame body 118.

  Here, the relationship of the force which the surface 134f which has the opening 135 of the developer accommodating member 134 receives by the top | upper surface 117a of the 1st frame 117 is shown below.

  As shown in FIG. 13B, a force acts on the bent portion 134n of the developer accommodating member 134 in the direction of the arrow F perpendicular to the top surface 117a of the first frame 117. Here, the bent portion 134n that connects the top surface 134k (third surface) and the surface 134f is a contact portion with the top surface 117a of the first frame 117. Therefore, the force received by the surface 134f of the developer storage member 134 can be expressed as follows using the angle θ13 described above.

[Force applied to the bent part]
Force component in a direction parallel to the surface 134f having the opening 135: F3x

F3x = F × cos | θ13−90 ° |
Force component in the direction perpendicular to the surface 134f having the opening 135: F3y

F3y = F × sin | θ13−90 ° |
Force component in the direction parallel to the top surface 117a of the first frame 117: F3yy

F3yy = F × sin | θ13−90 ° | × cos | θ13−90 ° |
= F × (sin (2 × | θ13−90 ° |)) / 2

  Here, the internal angle formed by the top surface 117a of the first frame body 117 and the surface 134f having the opening 135 of the developer storage member 134 has an angle θ13 of 90 ° <angle θ13 <180 °. Therefore, the force F3yy, which is a component of the force in the direction of the arrow F that works in the direction perpendicular to the top surface 117a, is the force F3yy> 0 and works in the direction of the arrow Q in FIG. Therefore, in the developer storage container 126, the bent portion 134n moves in the arrow Q direction, and the force F3x applied to the surface 134f having the opening 135 is released.

  Then, the surface 134f having the opening 135 of the developer storage member 134 falls to the inside of the developer storage member 134 (in the direction of arrow Q in FIG. 13B). As a result, the crushed developer storage container 126 is stored in the hatched portion K shown in FIG. Therefore, the surface 134f having the opening 135 can be accommodated between the first frame body 117 and the second frame body 118 while preventing bending and wrinkles.

  As described above, as shown in FIG. 13C, the developer container 126 is formed larger than the frame body 140 as in the fourth embodiment, but the first frame body 117 and the second frame body are formed. Therefore, the developer can be stored efficiently.

  By preventing the surface 134f having the opening 135 from being bent or wrinkled, the opening 135 can be prevented from being deformed, and the developer 39 can be supplied stably.

  In the above-described embodiment, the developer storage unit (or developing device) in the process cartridge is exemplified, but the present invention is not limited to this. The present invention is effective even with a developer storage unit (or developing device) that is provided separately from the process cartridge and is detachable from the image forming apparatus. Further, in the above-described embodiment, the configuration (development apparatus) in which the developer storage unit integrally has a developing roller as a developer carrying member is exemplified. However, as described above, the developer storage unit is provided with a separate developer roller. However, the present invention is effective.

  In the above-described embodiment, the process cartridge including the photosensitive drum is illustrated as being detachable from the image forming apparatus. However, the present invention is not limited to this. For example, it may be an image forming apparatus in which each constituent member is incorporated, or an image forming apparatus in which each constituent member is removable.

  In the above-described embodiments, the printer is exemplified as the image forming apparatus, but the present invention is not limited to this. For example, the image forming apparatus may be another image forming apparatus such as a copying machine or a facsimile machine, or another image forming apparatus such as a multi-function machine combining these functions. The same effect can be obtained by applying the present invention to these image forming apparatuses.

A ... Process cartridge B ... Image forming apparatus E ... Assembly direction F ... Longitudinal direction (long side direction)
P1, P2 ... reaction force T ... developer 11 ... photosensitive drum 13 ... developing roller 17 ... first frame 17a ... surface 18 ... second frame 18a ... surface 19 ... sealing member 20 ... opening member 24 ... Cleaner unit 25 ... developer storage unit 26 ... developer storage containers 26a, 26b ... end face 26a1, 26b1 ... end face 26c ... center face 26d, 26e ... side face 26d1, 26e1 ... convex part 26f, 26g ... inclined part Surface 26h ... Surface 34 ... Developer storage member 34a ... Molding portion 34b ... Ventilation portion 38 ... Developing device 40 ... Frame bodies 40a, 40b ... End surface 117 ... First frame body 117a ... Surface 118 ... Second frame body 118a ... surface 126 ... developer storage containers 126a, 126b ... end face 126c ... center face 126d, 126e ... end faces 126d1, 126e1 ... convex 126h ... face 128 ... 2nd frame 134a ... 1st shaping | molding part 134b ... 2nd shaping | molding part 140 ... Frame 140a, 140b ... End part surface 140c ... Center part surface 140d, 140e ... End surface 217 ... 1st frame 217a, 217b ... End Part surface 218 ... second frame 225 ... developer storage unit 226 ... developer storage container 226d, 226e ... side 234 ... developer storage member 234a ... molding part 234b ... ventilation part 240 ... frame bodies 240a, 240b ... end surface

Claims (11)

A developer storage unit for storing the developer,
A flexible container having an opening for discharging the developer and containing the developer;
A sealing member for sealing the opening;
The flexible container is housed and opened in a space formed by assembling the first frame to the second frame and having a first frame and a second frame. A frame for storing the developer discharged from the opening of the flexible container,
The flexible container has a long side end that has entered the first frame with respect to the second frame as compared to the first state where no external force is applied. A developer storage unit capable of taking two states.   The developer storage unit according to claim 1, wherein a gap is provided between an end surface in the long side direction of the flexible container and an end surface in the long side direction of the frame.   The developer storage unit according to claim 2, wherein the end surface of the flexible container is inclined with respect to the assembly direction.   3. The developer storage unit according to claim 2, wherein a thickness of the end surface of the flexible container is formed thinner than a thickness of a surface provided in a direction intersecting the assembly direction.   The distance of the widest portion between the surface facing the first frame and the surface facing the second frame in the assembling direction of the end portion in the long side direction of the flexible container is the flexibility. Characterized in that it is larger than the distance of the widest portion between the surface facing the first frame and the surface facing the second frame in the assembling direction of the central part in the long side direction of the conductive container. The developer storage unit according to claim 1.   The developer storage unit according to claim 1, wherein the flexible container includes a molding part and a ventilation part.   The developer storage unit according to claim 1, further comprising an opening unit that exposes the opening by moving the sealing member.   A developing device comprising: a developer carrier for developing a latent image formed on an image carrier using a developer; and the developer storage unit according to claim 1.   An image carrier, a developer carrier for developing a latent image formed on the image carrier using a developer, and the developer storage unit according to claim 1, To process cartridge.   The developer storage according to claim 1, a conveying means for conveying a recording medium, an image carrier, a developer carrier for developing a latent image formed on the image carrier using a developer, and the developer storage according to claim 1. An image forming apparatus comprising: a unit.   The flexible container has a first surface provided with the opening. When the first frame and the second frame are coupled, the flexible container is 2. The developer storage unit according to claim 1, wherein the first container is deformed by contacting with the second frame or the second frame, and the first surface falls to the inner side of the flexible container.

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