JP2020020910A - Developer storage unit, process cartridge and image formation device - Google Patents

Abstract

To improve sealing performance of a seal while reducing load for opening the seal to be compressed.SOLUTION: A developer storage unit includes: a frame body having an opening for discharging a developer; and a sealing unit which has a sealing section for sealing the opening, which is the sealing unit capable of shifting from a first state where the sealing section seals the opening to a second state where the opening is opened. The sealing section has a protrusion including a first portion and a second portion, and the protrusion can abut on the frame body in a peripheral portion of the opening. When the sealing unit is in the first state, the first portion abuts on the frame body at a downstream side of the opening and is inclined in a direction from an upstream side to the downstream side of the opening from a root to a tip of the first portion, and the second portion abuts on the frame body at the upstream side of the opening and is inclined in a direction from the downstream to the upstream side of the opening from a root to a tip of the second portion, a length from the root to the tip of the first portion is larger than a thickness of the first portion, and a length from the root to the tip of the second portion is larger than a thickness of the second portion.SELECTED DRAWING: Figure 6

Description

  The present invention relates to an image forming apparatus, a developer accommodating unit used in the image forming apparatus, and a process cartridge.

  2. Description of the Related Art In a conventional electrophotographic image forming apparatus using an electrophotographic forming process (hereinafter referred to as an apparatus main body), a process cartridge system in which a process cartridge in which an electrophotographic photosensitive member and a process means acting on the electrophotographic photoreceptor are integrated can be detachably attached to the apparatus main body. Has been adopted. In such a process cartridge system, an opening provided in a developer accommodating frame for accommodating a developer (toner, carrier, etc.) is sealed with a sealing member, and the process cartridge is shipped. When the process cartridge is used, the opening is opened by the user peeling off the joint of the toner seal as the sealing member, and the developer can be supplied to the apparatus main body.

  In recent years, in order to reduce the burden on the user, Patent Document 1 discloses a configuration in which the process cartridge is automatically opened by the driving force of the apparatus main body after the process cartridge is mounted on the apparatus main body. In the configuration described in Patent Literature 1, the seal member is detachably fixed to the developing container along the edge of the opening by heat welding or the like. When the rotating member in the developing container that stores the developer rotates, the seal member is wound around the rotating member, and the opening of the developing container is opened. On the other hand, in the configuration described in Patent Document 2, a sealing material is provided between an outer peripheral surface of a shutter that opens and closes an opening of a toner cartridge and an inner peripheral surface of the toner cartridge, and the toner is rotated by rotating the shutter. The cartridge has been opened. The shutter closes the opening in a state where the sealing material is compressed by the shutter.

JP 2014-167606 A JP 2013-134401 A

  In the case of a seal to be compressed, a certain force is required because the opening operation is started in a state where the seal is compressed when the seal is opened.

  An object of the present invention is to improve the sealing performance of a seal while reducing the opening load of the compressed seal.

To achieve the above object, the developer accommodating unit according to the present invention includes:
A frame provided with a developer storage chamber for storing the developer, and an opening for discharging the developer from the developer storage chamber;
A sealing unit provided inside the frame body,
A support portion rotatable in a first direction;
A sealing portion that is attached to the support portion and seals the opening by being compressed by the frame and the support portion, and includes a projection including a first portion and a second portion, A sealing portion configured so that the protruding portion can abut on the frame at a peripheral portion of the opening;
A sealing unit capable of shifting from a first state in which the sealing portion seals the opening to a second state in which the opening is opened,
With
When the sealing unit is in the first state, with respect to the first direction, the first portion abuts on the frame at a downstream side of the opening, and a root of the first portion. From the upstream toward the tip, it is inclined in a direction from the upstream side of the opening to the downstream side of the opening, the second portion abuts on the frame body on the upstream side of the opening, and the second portion Inclining in a direction from the downstream side of the opening toward the upstream side of the opening from the root of the portion toward the tip end,
When viewed in the direction of the rotation axis of the support, the length of the first portion from the root to the tip is greater than the thickness of the first portion,
The length of the second portion from the root to the tip is greater than the thickness of the second portion,
It is characterized by the following.

  ADVANTAGE OF THE INVENTION According to this invention, sealing performance can be improved, reducing the opening load of the seal | sticker compressed.

Sectional view of a process cartridge having a developer storage unit according to the embodiment. Sectional View of Image Forming Apparatus in Embodiment Sectional view of the developer accommodating unit according to the embodiment as viewed from the lateral direction. FIG. 2 is a perspective view illustrating assembly of a developer accommodating unit in the embodiment. Perspective view of a sealing unit in the embodiment Sectional view of the sealing unit in the embodiment Perspective view of a drive unit of a sealing unit in the embodiment Perspective view of an opening gear in the embodiment. Perspective view of an intermediate gear in the embodiment FIG. 4 is a view for explaining the operation of the sealing unit in the embodiment. Sectional view of the sealing unit in the comparative example Sectional view of the sealing unit in the embodiment Sectional view of the sealing unit in the embodiment

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, dimensions, materials, shapes, relative arrangements, and the like of the components described in the embodiments should be appropriately changed depending on the configuration of the apparatus to which the invention is applied, various conditions, and the like. The scope is not intended to be limited to the following embodiment.

  Here, the image forming apparatus forms an image on a recording medium using, for example, an electrophotographic image forming process, and includes, for example, an electrophotographic copying machine, an electrophotographic printer (for example, an LED printer, a laser beam printer, etc.), an electrophotographic A facsimile machine and the like are included. Further, the cartridge may be configured such that at least a developing unit and a developing device containing a developer are integrally formed so as to be detachable from an image forming apparatus main body, or a developing device and a photoconductor unit having at least a photoconductor are integrally formed. It is configured to be detachable from the image forming apparatus main body.

FIG. 1 is a sectional view of a process cartridge having a developer accommodating unit to which the present invention can be applied, and FIG. 2 is a sectional view of an image forming apparatus to which the present invention can be applied.
<Overview of process cartridge configuration>
The process cartridge includes an image carrier and a process unit that acts on the image carrier. Here, as the process means, for example, a charging means for charging the surface of the image carrier, a developing device for forming an image on the image carrier, and a developer (including a toner and a carrier) remaining on the surface of the image carrier are removed. There is a cleaning means for cleaning. The process cartridge A according to the present embodiment includes a cleaner unit 24 as shown in FIG. The cleaner unit 24 includes the photosensitive drum 11 as an image carrier, the charging roller 12 as a charging unit, and the elastic cleaning blade 14 as a cleaning unit. The charging roller 12 and the cleaning blade 14 are arranged around the photosensitive drum 11. Further, the process cartridge A includes a developer accommodating unit 25 having a first frame 17 and a second frame 18. The process cartridge A has a cleaner unit 24 and a developer accommodating unit 25 integrated therein, and is configured to be detachable from the image forming apparatus main body B as shown in FIG. The developer accommodating unit 25 includes a developing roller 13, a developing blade 15, a supply roller 23, and a developer accommodating chamber 26 for accommodating the developer. The developing roller 13 and the developing blade 15 are supported by the first frame 17.

<Configuration Overview of Image Forming Apparatus>
The process cartridge A is mounted on the image forming apparatus main body B shown in FIG. 2 and used for image formation. In image formation, a sheet (recording material) S is conveyed by a conveying roller 7 from a sheet cassette 6 mounted below the image forming apparatus main body B, and the photosensitive drum 11 is selected from the exposure device 8 in synchronization with the sheet conveyance. Exposure is performed, and a latent image is formed on the photosensitive drum 11. The developer is supplied to a developing roller (developer carrier) 13 by a sponge-like supply roller 23, and is carried on a thin layer on the surface of the developing roller 13 by a developing blade 15. A developing bias is applied to the developing roller 13 to supply the developer according to the latent image, thereby developing the developer image. As a result, a developer image is formed on the photosensitive drum 11, and the photosensitive drum 11 carries the developer image. The developer image on the photosensitive drum 11 is transferred to the sheet S by applying a bias voltage to the transfer roller (transfer section) 9. The sheet S is conveyed to the fixing device 10, and an image is fixed on the sheet S by the fixing device 10. The sheet S is discharged by a discharge roller 1 to a discharge unit 3 at an upper portion of the image forming apparatus main body B.

<Configuration of developer storage unit>
Next, the configuration of the developer accommodating unit 25 will be described with reference to FIGS. 1, 3, and 4. FIG. FIG. 3 is a cross-sectional view of the developer accommodating unit 25 cut along the axis of the developing roller 13, that is, a cross-sectional view of the developer accommodating unit 25 as viewed from the lateral direction. FIG. 4 is a perspective view showing the assembly of the developer storage unit 25. In the following description, the axial direction of the developing roller 13 is defined as the longitudinal direction, and the direction orthogonal to the longitudinal direction is defined as the lateral direction. As shown in FIG. 1, the developer accommodating unit 25 is configured such that a first frame 17 supporting the developing roller 13 and the developing blade 15 and a second frame 18 are united to form one developing frame (frame). Constitute. The first frame 17 and the second frame 18 form a developer storage chamber 26 inside the developer storage unit 25. An opening 17a for discharging the toner stored in the developer storage chamber 26 is provided in a lower portion of the first frame body 17 over a wide area in the longitudinal direction. In other words, the developing frame is provided with the developer accommodating chamber 26 and the opening 17a.

A sealing unit 20 for closing the opening 17 a is provided inside the developer accommodating chamber 26. In FIG. 1, the sealing unit 20 is provided inside the first frame 17. The sealing unit 20 has a shape extending in the longitudinal direction along the opening 17a, and the sealing portion 20b having elasticity and the supporting portion 20a supporting the sealing portion 20b are integrally connected. . As shown in FIG. 3, shaft portions 20 c and 20 d are provided at both ends of the support portion 20 a, and the sealing unit 20 (support portion 20 a) is rotatably supported by the first frame 17. Further, an opening gear 41 is connected to the shaft portion 20d at one end (the right side in FIG. 3), and the sealing unit 20 and the opening gear 41 rotate integrally. The opening gear 41 is engaged with the input gear 43 via the intermediate gear 44. When the process cartridge A is shipped, the sealing unit 20 is disposed at a position where the opening 17a is sealed by the sealing portion 20b as shown in FIG. When the process cartridge A is used, when the input gear 43 is driven by the image forming apparatus main body B and rotates, the sealing unit 20 rotates in the direction of the arrow R in FIG. 1 and the opening 17a is opened. . The state in which the sealing unit 20 (the sealing portion 20b) seals the opening 17a is referred to as a sealed state or a first state. When the sealing unit 20 is in the sealed state, the discharge of the toner from the opening 17a is restricted. Further, a state in which the sealing unit 20 (the sealing portion 20b) is at a position where the opening 17a is exposed is referred to as an unsealed state or a second state. When the sealing unit 20 is in the unsealed state, the opening 17a is open. Then, the discharge of the toner from the opening 17a is permitted. The support portion 20a is rotatable around an axis g (rotation axis) described later. The direction in which the support unit 20a rotates so that the sealing unit 20 shifts from the sealing state to the unsealing state is referred to as an unsealing direction or a first direction (rotation direction R). After the sealing unit 20 is in the unsealed state, the sealing unit 20 may rotate in a direction opposite to the rotation direction R (a second direction) within a range in which the sealing portion 20b does not block the opening 17a. It is possible to repeatedly exercise toward R. That is, after the sealing unit 20 is opened, the sealing unit 20 can reciprocate. The configuration of the sealing unit 20 will be described later in detail.

  Further, a developing roller 13 and a supply roller 23 for supplying toner to the developing roller 13 are provided outside the developer accommodating chamber 26. Both longitudinal ends of the developing roller 13 and the supply roller 23 are rotatably supported by the first frame 17. The developing gear 42 is connected to one longitudinal end of the developing roller 13, and the developing gear 42 is engaged with the input gear 43. A gear (not shown) is connected to one longitudinal end of the supply roller 23, and the gear (not shown) is engaged with the input gear 43. The rotation of the input gear 43 causes the developing roller 13 and the supply roller 23 to rotate together with the opening gear 41. As shown in FIGS. 3 and 4, a plurality of rib-shaped pressing portions 18a protrude from the inner top surface of the second frame 18 toward the opening 17a (downward in FIGS. 3 and 4). The pressing portion 18a is provided inside the second frame 18 at a position facing the opening surface of the opening 17a, and contacts the pressed portion 20e provided in the sealing unit 20 in a sealed state. The sealing portion 20b is attached to the support portion 20a, and seals the opening 17a by being sandwiched between the first frame 17 and the support portion 20a. In other words, the sealing portion 20b is pressed against the peripheral portion of the opening 17a in the first frame 17 and compressed by the support portion 20a. That is, the sealing portion 20 b is compressed by the support portion 20 a and the first frame 17. Then, the opening 17a is sealed by the sealing portion 20b. That is, the sealing portion 20b can abut on the first frame 17 at a portion around the opening 17a. The sealed state indicates a state in which the sealing unit 20 seals the opening 17a. The function of the holding portion 18a will be described later.

<Detailed configuration of sealing unit 20>
Next, a detailed configuration of the sealing unit 20 will be described with reference to FIGS. 4, 5, 6, 11, and 12. FIG. FIG. 5 is a perspective view of the sealing unit 20, and FIGS. 6 and 12 are cross-sectional views of the sealing unit 20. FIG. 6A illustrates a state before the sealing unit 20 is incorporated in the developer accommodating chamber 26, and FIG. 6B illustrates a state in which the sealing unit 20 is incorporated in the developer accommodating chamber 26. FIGS. 6C to 6E are views for explaining the opening operation of the sealing unit 20. FIG. 11 is a cross-sectional view of the sealing unit 120 in the comparative example. FIG. 12A is an enlarged view of FIG. Similarly, FIG. 12B is an enlarged view of FIG. 6B with additional dimensions. As described above, the sealing unit 20 includes the support portion 20a and the elastic sealing portion 20b. In the present embodiment, an elastomer resin is used as a material of the sealing portion 20b, and a polystyrene resin is used as a material of the supporting portion 20a. In this case, the rigidity of the sealing portion 20b is lower than the rigidity of the supporting portion 20a. Regarding the manufacturing method, the sealing portion 20b and the support portion 20a may be individually manufactured and then joined to each other, but the sealing portion 20b and the support portion 20a may be sealed by using an elastomer resin as a material of the sealing portion 20b. The portion 20b may be integrally formed. By integrally molding the supporting portion 20a and the sealing portion 20b, a joining step of the two members is not required, and the productivity can be improved. Further, the material of the sealing portion 20b is not limited to the elastomer resin. For example, another material having elasticity may be used as the material of the sealing portion 20b,
The resin is not limited to the elastomer resin as long as it has an appropriate shape and setting so that the sealing property is maintained with respect to the toner in the storage container and the opening load is not greater than that of the conventional one as described later.

  Next, the shape of the sealing portion 20b will be described in detail. The sealing part 20b has a base part 20b0 and a protruding part including the lips 20b1 to 20b4. When the sealing unit 20 is in the sealed state, the protruding portion of the sealing portion 20b abuts on the first frame 17 at the periphery of the opening 17a. As shown in FIG. 5B, in the sealing portion 20b, lips 20b1 to 20b4 that protrude from the elongated rectangular base 20b0 are formed along the outer peripheral portion of the base 20b0. That is, the lips 20b1 to 20b4 stand upright on the outer peripheral portion of the base 20b0, and the lip 20b1 to 20b4 forms a frame member on the outer peripheral portion of the base 20b0. The lips 20b1 to 20b4 protrude from the base 20b0 toward the opposite side of the support 20a. The upper surface of the base 20b0 is a joint surface with the support 20a. Here, in the rotation direction R, the lip 20b1 is located downstream of the lip 20b2. The lips 20b1 and 20b2 extend in the direction of the rotation axis (axis g) of the support portion 20a. That is, the longitudinal direction of the lips 20b1 and 20b2 is the direction of the rotation axis (axis g) of the support portion 20a. The lip 20b3 and the lip 20b4 extend in a direction (rotational direction of the support 20a) intersecting with the rotation axis (axis g) of the support 20a. That is, the longitudinal direction of the lips 20b3 and 20b4 is a direction (rotational direction of the support portion 20a) that intersects with the rotation axis (the axis g) of the support portion 20a. Each of the inner surfaces of the lips 20b1 to 20b4 faces the inside of the base 20b0. Each of the outer surfaces of the lips 20b1 to b4 faces the outer direction of the base 20b0. The inner surface of the lip 20b1 faces the inner surface of the lip 20b2, and the inner surface of the lip 20b3 faces the inner surface of the lip 20b4. In the sealed state, as shown in FIG. 6B, the lips 20b1 to b4 are arranged so as to surround the outer periphery of the opening 17a. That is, in the case of the sealing state, the supporting portion 20a urges the lips 20b1 to b4 against the peripheral portion of the opening 17a in the first frame 17, and the lips 20b1 to b4 Abut the surrounding area. When the sealing unit 20 is in the sealed state, the tip of the lip 20b1 (first portion) is positioned downstream of the root of the lip 20b1 in the rotation direction R, and the lip 20b2 (second portion) The tip is located upstream of the base of the lip 20b2. In the sealed state, the lips 20b1 and 20b2 provided on the long side of the base 20b0 are deformed into a shape along the arc shape of the contacted portions 17b and 17c of the first frame 17. In the sealed state, the lips 20b3 and 20b4 provided on the short side of the base 20b0 are deformed into a shape along the arc shape of the contacted portion 17d of the first frame 17. The abutted portions 17b, 17c, and 17d are inside portions of the first frame 17 and are included in the first frame 17 around the opening 17a.

  As for the cross-sectional dimensions of the lips 20b1 to b4, as shown in FIG. 6A, for example, the height H1 is 2.8 mm and the width W is 1 mm. When the sealing unit 20 is in the sealed state (FIG. 6B), the sealing unit 20b is deformed, and the sealing unit 20 is supported by the first frame 17. For example, the sealing unit at this time The distance H2 between the base 20b0 of 20b and the opening 17a is 2.1 mm, and H1> H2 when the sealing portion 20b is deformed.

The tip shapes of the lips 20b1 to b4 will be specifically described with reference to FIGS. A distance L1 from a straight line D1 passing through the end face 17b1 of the opening 17a to a straight line D2 passing through the base of the lip 20b1 is smaller than a distance L2 from a straight line D1 passing through the end face 17b1 to a straight line D3 passing through the tip of the lip 20b1. That is, the lip 20b1 is provided on the base 20b0 so that the distance L1 <the distance L2 is satisfied. The same applies to the lips 20b2 to b4. The base of the lip 20b1 is a boundary between the base 20b0 and the lip 20b1. The straight line D2 is a straight line drawn from the base of the lip 20b1 toward the contacted portion 17b of the first frame 17. The straight line D3 is a straight line drawn from the tip of the lip 20b1 toward the contacted portion 17b of the first frame 17. The distance L2 is larger than the distance L1. Therefore, the lip 20b1 is inclined toward the outside of the base 20b0. Similarly, the lips 20b2 to b4 are inclined to the outside of the base 20b0.

  As shown in FIG. 12B, the sealing unit 20 is incorporated in the developer accommodating chamber 26. In a state where the sealing portion 20b seals the opening 17a, the tip of the lip 20b1 is in contact with the contacted portion 17b, and the tip of the lip 20b2 is in contact with the contacted portion 17c. That is, when the sealing unit 20 is in the sealed state, the lip 20b1 abuts on the first frame 17 on the downstream side of the opening 17a in the rotation direction R. In the rotation direction R, the lip 20b2 contacts the first frame 17 on the upstream side of the opening 17a. At this time, the support portion 20a is pressed by the pressing portion 18a, and the lips 20b1 to 20b4 are in a deformed state. In this case, the lip 20b1 is inclined in a direction from the upstream side to the downstream side of the opening 17a from the root to the tip of the lip 20b1. The lip 20b2 is inclined in a direction from the downstream side to the upstream side of the opening 17a from the root to the tip of the lip 20b2. The upstream side of the opening 17a coincides with the upstream side in the rotation direction of the sealing unit 20. The downstream side of the opening 17a coincides with the downstream side in the rotation direction of the sealing unit 20.

  The lip 20b1 is tilted in a direction in which the tip of the lip 20b1 is further away from the opening 17a than before the tip of the lip 20b1 contacts the contacted portion 17b (FIG. 12A). In other words, the distance L3 between the straight line D2 and the straight line D3 on the lip 20b1 in FIG. 12B is larger than the distance (L2-L1) between the straight line D2 and the straight line D3 on the lip 20b1 in FIG. Is larger. In other words, when the tip of the lip 20b1 that is inclined before the sealing unit 20 is installed in the developer storage chamber 26 falls down in a certain direction when the sealing unit 20 is installed in the developer storage chamber 26, The lip 20b1 contacts the contacted portion 17b. In other words, a part of the inner surface of the lip 20b1 contacts the periphery of the opening 17a in the first frame 17, and a part of the inner surface of the lip 20b2 contacts the periphery of the opening 17a in the first frame 17. Touch The same deformation is performed over the entire circumference of the sealing portion 20b, and the lips 20b1 to b4 are attached to the first frame while the tips of the lips 20b1 to b4 are tilted away from the opening 17a. 17 is in contact with the peripheral portion of the opening 17a.

  As shown in FIG. 13, when viewed in the direction of the rotation axis (axis g) of the support portion 20a, the length L4 from the base to the tip of the lip 20b1 is larger than the thickness T1 of the lip 20b1, and from the base of the lip 20b2. The length L5 to the tip is larger than the thickness T2 of the lip 20b2. Note that viewing in the direction of the rotation axis (axis g) refers to viewing the object projected on a plane orthogonal to the rotation axis (axis g) along the direction of the rotation axis. Therefore, the lip 20b1 and the lip 20b2 tend to fall in the rotation direction R of the sealing unit 20. In the present embodiment, the length L4, the thickness T1, the length L5, and the thickness T2 are measured as follows. In the projecting direction of the lip 20b1, the length of the portion of the lip 20b1 projecting from the base 20b0 is defined as a length L4 from the root to the tip of the lip 20b1. In a direction perpendicular to the direction in which the lip 20b1 protrudes and along the rotational direction R of the sealing unit 20, the distance between the outer surface of the lip 20b1 and the inner surface opposite to the outer surface is determined by the distance of the lip 20b1. It is assumed that the thickness is T1. In the projecting direction of the lip 20b2, the length of the portion of the lip 20b2 projecting from the base 20b0 is defined as a length L5 from the base to the tip of the lip 20b2. In a direction perpendicular to the direction in which the lip 20b2 protrudes and along the rotational direction R of the sealing unit 20, the distance between the outer surface of the lip 20b2 and the inner surface opposite to the outer surface is determined by the distance of the lip 20b2. The thickness is T2.

In the configuration of the embodiment, the lip 20b1 is provided on the base 20b0 such that the length L4 from the base to the tip of the lip 20b1 is greater than the thickness T1 of the lip 20b1. In the configuration of the embodiment, the length L5 from the root to the tip of the lip 20b2 is different from the lip 20b.
The lip 20b2 is provided on the base portion 20b0 so as to be larger than the thickness T2 of the base 2b. The lips 20b3 and 20b4 also have a shape whose length is greater than the thickness. The thickness direction of the lips 20b3 and 20b4 is the direction of the rotation axis of the support portion 20a. As a result, the lip 20b1 and the lip 20b2 tend to fall down, so that the sealing state is maintained even when the sealing portion 20b exerts a small pressure on the peripheral portion of the opening 17a in the first frame 17. By reducing the urging pressure on the periphery of the opening 17a in the first frame 17, the load when opening the opening 17a can be reduced. Therefore, the sealing performance of the sealing unit 20 can be improved while reducing the opening load of the sealing unit 20 to be compressed. In addition, since the lip 20b1 and the lip 20b2 tend to fall in the rotation direction R of the sealing unit 20, the sealing unit 20 can rotate with the lip 20b1 and the lip 20b2 falling, and the opening 17a is opened. Load is reduced. When the thickness T1 of the lip 20b1 is larger than the length L4 from the root to the tip of the lip 20b1, the lip 20b1 is unlikely to fall in the rotation direction R of the sealing unit 20. When the thickness T2 of the lip 20b2 is larger than the length L5 from the root to the tip of the lip 20b2, the lip 20b2 is unlikely to fall in the rotation direction R of the sealing unit 20.

  If the distance L1 between the straight line D1 and the straight line D2 is the same as the distance L2 between the straight line D1 and the straight line D3 (L1 = L2), when the sealing unit 20 is incorporated in the developer accommodating chamber 26, The direction in which the lip 20b1 falls down is not stable. When the lips 20b1 to b4 fall down unevenly, there is a concern that toner may leak from a gap between the lips 20b1 to b4 and a portion around the opening 17a in the first frame 17. In the embodiment, each tip of the lips 20b1 to 20b4 faces the direction away from the opening 17a, that is, the direction of the toner storage area. The tips of the lips 20b1 to b4 are pressed against the abutted portions 17b, 17c, and 17d by the toner powder pressure in the developer accommodating chamber 26, so that the tips of the lips 20b1 to b4 are in the opening 17a. The sealing performance is superior to the configuration facing the approaching direction. The corners where the lips 20b1 and 20b2 provided on the long side of the base 20b0 intersect with the lips 20b3 and 20b4 provided on the short side of the base 20b0 are arc-shaped (FIG. 5B).

  As described above, the sealing portion 20b is sandwiched between the support portions 20a and the contact portions 17b, 17c, 17d (FIG. 4) all around the opening 17a, and the sealing portions for the contact portions 17b, 17c, 17d are provided. The direction in which the lips 20b1 to b4 fall down is fixed by the contact of the lip 20b. Therefore, the sealed state is stably maintained.

  As shown in FIG. 6A, the support portion 20a is provided with a pressed portion 20e at a position opposite to the sealing portion 20b and facing the pressing portion 18a. The pressing portion 18a comes into contact with the pressed portion 20e, the sealing portion 20b is slightly deformed, and the sealing unit 20 maintains the sealing state (FIG. 6B). That is, when the pressed portion 20e contacts the pressing portion 18a, the pressed portion 20e contacts the peripheral portion of the opening 17a in the first frame 17 in a state where the shapes of the lips 20b1 to b4 are deformed. Accordingly, it is possible to suppress a decrease in sealing performance due to the support portion 20a being warped by the elasticity of the sealing portion 20b. Further, deformation of the sealing unit 20 due to vibration or the like during distribution can prevent toner from leaking from the opening 17a. Further, by providing the pressing portion 18a on the second frame 18, the bending rigidity of the support portion 20a can be made weaker than when the pressing portion 18a is not provided on the second frame 18. In addition, it contributes to material saving and weight reduction of the support portion 20a. In the embodiment, the number of the pressing portions 18a is three at the second frame body 18 in the embodiment. However, the number may be appropriately selected depending on the rigidity of the supporting portion 20a and the elasticity of the sealing portion 20b. Further, the number of the pressed portions 20e is selected according to the number of the pressed portions 18a.

When the sealing unit 20 is driven by the image forming apparatus main body B, as shown in FIG. 6B, the sealing unit 20 rotates in the direction of arrow R about an axis g connecting the shaft portions 20c and 20d at both ends. Here, the sealing unit 120 in the comparative example of FIG. 11 will be described. The sealing unit 120 in the comparative example includes a support portion 120a and a strip-shaped sponge 120b, and the sponge 120b covers the opening 117a. The sealing unit 120 is rotatably supported via a shaft 120d. In the comparative example, when the opening of the opening 117a is started, the abutted portions 117b and 117c are rubbed while the sponge 120b maintains the compressed state. On the other hand, in the configuration of the sealing unit 20 in the embodiment, as shown in FIG. 6C, the tip of the lip 20b1 on the downstream side in the rotation direction R slides from the position where the lip 20b1 contacts the contacted portion 17b. Flip inward without doing. That is, when the sealing unit 20 shifts from the sealing state to the unsealing state, the tip of the lip 20b1 is located upstream of the root of the lip 20b1 in the rotation direction R of the sealing unit 20, and the tip of the lip 20b2 is It is located on the upstream side in the rotation direction R of the sealing unit 20 from the root of 20b2. In other words, when the sealing unit 20 shifts from the sealed state to the unsealed state, the lip 20b1 is deformed so that the tip of the lip 20b1 is located upstream of the root of the lip 20b1 in the rotation direction R. On the other hand, when the sealing unit 20 shifts from the sealing state to the unsealing state, the tip of the lip 20b2 is located upstream of the root of the lip 20b2 in the rotation direction R. That is, the inclination direction of the lip 20b2 does not change. The opened state indicates a state in which the sealing unit 20 opens the opening 17a. In this case, a part of the outer surface of the lip 20b1 contacts the periphery of the opening 17a in the first frame 17, and a part of the inner surface of the lip 20b2 contacts the periphery of the opening 17a in the first frame 17. . Thereafter, the lip 20b1 is rubbed while maintaining the inverted posture. Therefore, according to the configuration of the embodiment, the load of opening can be reduced as compared with the configuration of the comparative example using the strip-shaped sponge 120b. As described above, the lip 20b1 and the lip 20b2 tend to fall in the rotation direction R of the sealing unit 20. Therefore, even when the tip of the lip 20b1 does not turn inward, the configuration of the embodiment is a strip-shaped sponge. The load of opening is lower than the configuration of the comparative example using 120b. In the configuration of the embodiment, the toner is easily transported by the lip 20b1 and the lip 20b2.

  A concave arc shape following the convex arc shape of the pressing portion 18a is formed on the contact surface of the pressed portion 20e with the pressing portion 18a. Further, a concave shape following the convex shape of the pressing portion 18a may be formed on the contact surface of the pressed portion 20e with the pressing portion 18a. With this configuration, the phase of the sealing unit 20 is stabilized when the sealing unit 20 is assembled. In addition, it is possible to prevent the sealing unit 20 from shifting in the circumferential direction due to vibration during distribution. An escape portion 20g is provided on the upstream side in the rotation direction R of the pressed portion 20e so as to be retracted inside the rotation radius K of the pressed portion 20e. That is, the sealing unit 20 has a concave portion provided inside the rotation radius K of the pressed portion 20e. When the sealing unit 20 rotates in the direction of the arrow R, when the pressed portion 20e separates from the pressing portion 18a and the escape portion 20g reaches the position of the pressing portion 18a, the support portion 20a causes the elastic reaction force of the sealing portion 20b. As a result, it warps to the opposite side of the sealing portion 20b. By doing so, the pressure at which the sealing portion 20b urges the peripheral portion of the opening 17a in the first frame 17 on the inside in the longitudinal direction is reduced, and as a result, the opening load is reduced. The sealing unit 20 receives the drive from the image forming apparatus main body B, and moves from the first position shown in FIG. 6B to the direction of arrow R in the figure as shown in FIG. , Referred to as the opening angle). Therefore, by rotating the sealing unit 20, it is possible to shift from the first state in which the sealing unit 20 seals the opening 17a to the second state in which the sealing unit 20 opens the opening 17a. The opening operation of the sealing unit 20 is performed by such an operation. As shown in FIG. 6D, in the second state in which the sealing unit 20 opens the opening 17a, at least a part of the pressing portion 18a is located in the concave portion of the pressed portion 20e, and the inner side surface of the concave portion ( A gap is formed between the escape portion 20g) and the pressing portion 18a. That is, when the sealing unit 20 is in the unsealed state, a gap is formed between the inner side surface of the concave portion (the escape portion 20g) and the pressing portion 18a. Further, since the sealing portion 20b has elasticity, as shown in FIG. 6D, the pressed portion 20e is separated from the pressing portion 18a, so that the shapes of the lips 20b1 to b4 are deformed. Return to the original state before deformation.

  Further, the sealing unit 20 does not stay at the second position, but as shown in FIG. 6E, a second predetermined angle θ2 (hereinafter referred to as a maximum angle) from the first position in the direction of arrow R in the figure. ), And moves to a third position where it does not contact the pressing portion 18a. Immediately thereafter, the sealing unit 20 reverses in the direction of arrow C in FIG. 6E and returns to the second position shown in FIG. Thereafter, similarly, the sealing unit 20 keeps repeating the reciprocating movement between the second position and the third position. In the embodiment, the drive configuration is set such that the opening angle θ1 is 77 degrees and the maximum angle θ2 is 95 degrees. The above operation of the sealing unit 20 can be realized by, for example, a link mechanism, but in the embodiment, is realized by using a toothless gear and a spring. The opening angle θ1 and the maximum angle θ2 can be set arbitrarily according to the specifications of the gear. The details of the drive configuration will be described later.

  Meanwhile, as shown in FIG. 5A, a plurality of ribs 20f are provided on the support portion 20a at positions opposite to the sealing portion 20b. As shown in FIG. 5A, the rib 20f is inclined at 45 degrees with respect to the axis g connecting the shaft portions 20c and 20d. The plurality of ribs 20f are arranged so that the inclination directions are different from each other at the center of the longitudinal direction of the sealing unit 20. The rib 20f is inclined toward the outer side in the longitudinal direction of the sealing unit 20 from the upstream side to the downstream side in the rotation direction R of the sealing unit 20. By arranging the ribs 20f in this way, when the sealing unit 20 is located between the second position and the third position, the ribs 20f are moved from the upper side to the lower side in the direction of gravity in the direction of the sealing unit 20. The posture is inclined toward the inside of the longitudinal direction. With such a configuration of the rib 20f, the sealing unit 20 reciprocates between the second position and the third position, thereby agitating the toner in the developer accommodating chamber 26 while maintaining the longitudinal center of the sealing unit 20. Can be collected slowly. Therefore, for example, even when the toner is biased to one end in the longitudinal direction of the sealing unit 20, the toner can be quickly brought to the longitudinal center of the sealing unit 20, so that the idling time before outputting an image can be reduced. it can.

  In the embodiment, the sealing unit 20 performs a reciprocating motion after opening, so that the sealing unit 20 has a stirring function. For example, when the sealing unit 20 rotates, the sealing unit 20 interferes with the pressing portion 18a. Therefore, when the sealing unit 20 rotates, sealing by welding is required. That is, when the sealing means having the stirring function is automatically opened in the apparatus main body, a structure in which a film is welded around the opening of the frame, and the film is wound around a shaft provided in the frame and peeled off is generally used. It is a target. However, according to the embodiment, it is possible to realize the sealing unit 20 having a stirring function that does not require welding. In addition, in the embodiment, since the opening is performed by moving the energized sealing portion 20b, the opening load is reduced as compared with the opening load in which the welded member is peeled (that is, mechanically broken). can do.

  Further, in the case of sealing by welding, the welding surface, that is, the surface around the opening needs to be flat for the stability of welding. However, since there is no such restriction in the configuration of the embodiment, the surface around the opening 17a can be formed in an inclined shape or an arc shape that is directed downward in the direction of gravity toward the opening 17a. As a result, the toner around the opening 17a tends to drop toward the opening 17a, and the configuration of the embodiment improves the discharge performance as compared with the conventional fusion sealing configuration.

Further, as shown in FIG. 6B, the center of rotation g of the sealing unit 20 is located on the upstream side (in the moving direction of the sealing portion 20b at the start of opening) with respect to the arc center h of the contacted portion 17d. (Right side in the figure) at a position offset by about 2 mm. With this configuration, when unsealing, the lips 20b3, b4 (see FIG. 5) provided on the short side of the base 20b0 gradually separate from the contacted portion 17d in the radial direction of the arc of the contacted portion 17d. , The sealing part 20b moves. In the case where the arc center h and the rotation center g coincide (hereinafter, referred to as concentric configuration), in the unsealing operation, the sealing portion 20b keeps rubbing the bottom surface of the first frame 17, so that the unsealing torque is reduced. High state persists. According to the configuration of the embodiment, since the friction load gradually decreases from the start of opening, the opening torque can be gradually reduced from the start of opening compared to the concentric configuration. Further, by disposing the arc center h and the rotation center g to be displaced, the sealing unit 20 that reciprocates at the second position and the third position can rotate the sealing unit 20 with respect to the bottom surface of the first frame 17. It can be separated in the K direction. Therefore, the gap d (FIG. 6D) between the sealing unit 20 and the bottom surface of the first frame 17 can be provided widely. As a result, the toner in the developer accommodating chamber 26 can be smoothly discharged from the opening 17a without being hindered by the sealing unit 20. Further, compared with the configuration in which the sealing portion 20b rubs against the inner surface of the first frame 17, the configuration of the embodiment can further reduce the toner stress. On the other hand, in the case of the concentric configuration, the sealing unit 20 is separated from the bottom surface of the first frame 17 by moving the lip 20b2 on the upstream side in the rotation direction R to the contacted portion 17b on the upstream side in the rotation direction R. Can be done. That is, in order to provide the gap d between the sealing unit 20 and the bottom surface of the first frame 17, it is necessary to rotate the sealing unit 20 further in the rotation direction R than the second position.

<Driving Configuration of Sealing Unit 20>
Next, the operation of the sealing unit 20 will be described with reference to FIGS. 7, 8, 9, and 10. FIG. FIG. 7 is a perspective view showing a driving unit of the sealing unit 20, and FIG. 8 is a perspective view showing an opening gear 41. FIG. 9 is a perspective view showing the intermediate gear 44, and FIG. 9B is a view of the intermediate gear 44 viewed from the opposite direction of FIG. 9A. FIG. 10 is a diagram for explaining the operation of the sealing unit 20. The sealing unit 20 operates in the order of FIGS.

  As shown in FIG. 7, the opening gear 41 connected to the sealing unit 20 is provided at a longitudinally outer end of the first frame 17. Then, as shown in FIG. 8, in the order closer to the first frame 17, the stepped gear formed by the first opening gear portion 41a (41a1, a2) and the second opening gear portion 41b (41b1 to b5) is formed. Are located. As shown in FIG. 8, the first opening gear portion 41a has two teeth (41a1, a2) spaced apart by five teeth, and all other teeth have been deleted from the gear having a total of 28 teeth. It is a missing tooth gear. On the other hand, the second opening gear portion 41b is a missing tooth gear in which five consecutive teeth (41b1 to b5) are left out of the gear having a total of 28 teeth and all other teeth are deleted. Five consecutive teeth of the second opening gear portion 41b are provided between two teeth of the first opening gear portion 41a. An arcuate concave portion 41c is provided on the downstream side in the rotation direction R of the second opening gear portion 41b. As shown in FIG. 8, when viewed from the longitudinal direction, one tooth on the downstream side in the rotation direction R of the first opening gear portion 41a on a straight line M connecting the arc center of the arc concave portion 41c and the rotation center of the opening gear 41. The center of 41a1 (hereinafter referred to as the leading tooth) is located. In the embodiment, a part of the center of the arc concave portion 41c is retracted following the root arc of the second opening gear portion 41b. This is for the purpose of simplifying the mold configuration of the opening gear 41, and as long as it is projected from the longitudinal direction and an arc shape is provided at both ends of the tip tooth 41a1, there is no problem in function as described later.

  As shown in FIG. 9, the intermediate gear 44 that engages with the opening gear 41 also has a stepped gear configuration. A first intermediate gear portion 44a (44a1 to a5) and a second intermediate gear portion 44b (44b1 to b5) which engage with the first opening gear portion 41a and the second opening gear portion 41b, respectively; A third intermediate gear portion 44d to be engaged is provided. The third intermediate gear portion 44d is a normal all-tooth gear. In order to facilitate understanding of the first intermediate gear portion 44a and the second intermediate gear portion 44b, the third intermediate gear portion 44d is shown by a broken line in FIG. The first intermediate gear portion 44a is a missing tooth gear in which five teeth (44a1 to a5) at equal intervals apart from two teeth and all other teeth are deleted from a gear having a total of 15 teeth. is there. The second intermediate gear portion 44b is a missing tooth gear in which five consecutive teeth are left out of the gear having a total of 15 teeth, and the other circumference is formed by an arc portion 44c having the same outer diameter as the tip circle.

Next, the operation of the sealing unit 20 when the input gear 43 rotates by receiving rotation from the image forming apparatus main body B will be described with reference to FIGS. In FIGS. 10A to 10F, illustration of the third intermediate gear portion 44d is omitted for easy understanding. FIG. 10 (a)
As shown in (2), when the sealing unit 20 is in the sealed state, the arc-shaped concave portion 41c of the opening gear 41 engages with the arc-shaped portion 44c of the intermediate gear 44. When the intermediate gear 44 rotates in the direction of the arrow L in response to the rotation of the input gear 43 (not shown), first, one tooth 44a1 of the first intermediate gear portion 44a provided on the upstream side in the rotation direction L of the arc portion 44c is The rotation drive is transmitted to the tip teeth 41a1 provided on the upstream side in the rotation direction R of the arcuate recess 41c. Then, the opening gear 41 starts rotating in the arrow R direction. Then, as shown in FIGS. 10 (b) and 10 (c), the opening gear 41 rotates as the opposing teeth of the second intermediate gear portion 44b and the second opening gear portion 41b are sequentially engaged. Here, in the sealed state, the first intermediate gear portion 44a is separated by two teeth as described above. On the other hand, since the circular arc concave portion 41c of the opening gear 41 is engaged with the circular arc portion 44c of the intermediate gear 44, the rotational drive does not propagate backward from the sealing unit 20 to the upstream side (reverse side). That is, the lock mechanism can prevent the sealing unit 20 from being accidentally rotated due to vibration or the like during physical distribution.

  FIG. 10D shows a state in which the engagement between the second intermediate gear portion 44b and the second opening gear portion 41b is completed. The sealing unit 20 moves from the first position in the sealed state to the second position rotated by the opening angle θ1 in the direction of arrow R in FIG. 10D, and the opening is completed. In this case, the biasing spring 21 provided on the first frame 17 contacts the biased portion 41 d of the opening gear 41. The biasing spring 21 is a torsion coil spring, and the winding portion 21a is engaged with a boss 17e provided on the side surface of the first frame 17. The biasing spring 21 is arranged so that one arm 21b contacts the biased portion 41d of the opening gear 41 and the other arm 21c contacts the regulating rib 17f of the first frame 17. . In this state, the biased portion 41d is formed so as to be parallel to the arm portion 21b. Thereby, the opening gear 41 does not rotate in the direction opposite to the arrow R from this phase. That is, once the sealing unit 20 has moved to the second position, it does not return to the first position more than the second position. Therefore, after shifting from the sealing state to the unsealing state, the state does not shift from the unsealing state to the sealing state. When the intermediate gear 44 further rotates in the direction of arrow L, one tooth 44a4 of the first intermediate gear portion 44a becomes the other tooth 41a2 of the first opening gear portion 41a that does not contribute to opening (hereinafter referred to as a terminal tooth). ), The opening gear 41 further rotates in the direction of arrow R. In this case, the biasing spring 21 acts to prevent the opening gear 41 from rotating in the direction of arrow R. After the opening gear 41 rotates in the direction of arrow R by about one tooth from the state of FIG. 10D, the drive transmission from the intermediate gear 44 is cut off because the first intermediate gear portion 44a is missing teeth.

  As shown in FIG. 10E, the opening gear 41 is rotated by the urging spring 21 in the direction of arrow C in the figure, and returns to the position shown in FIG. The position (third position) of the sealing unit 20 at the moment when the transmission of the drive from the intermediate gear 44 is cut off is a position in which the maximum angle θ2 is opened in the direction of arrow R from the first position in the sealed state. The intermediate gear 44 continues to rotate in the arrow L direction thereafter, as shown in FIG. One tooth 44a5 on the upstream side in the rotation direction L from the one tooth 44a4 of the first intermediate gear portion 44a that has driven the opening gear 41 from the second position to the third position comes into contact with the terminal tooth 41a2, and the opening gear 41 Starts rotating in the direction of arrow R again. By repeating the first intermediate gear portion 44a intermittently contacting the terminal teeth 41a2 of the opening gear 41, the sealing unit 20 repeats the reciprocating movement between the second position and the third position. As described above, the unsealing operation and the stirring operation can be realized with a simple component configuration using the pair of missing tooth gears and the spring. Further, by adopting the driving configuration according to the embodiment, the movement start acceleration in the direction in which the sealing unit 20 returns from the third position to the second position by the biasing spring 21 is such that the sealing unit 20 has the second position. It becomes larger than the movement start acceleration of moving from the position to the third position by the gear. By providing a difference in the reciprocation movement start acceleration of the sealing unit 20 in this manner, the toner attached to the sealing unit 20 is shaken off, so that more toner in the developer storage chamber 26 can be used.

17 first frame, 17a opening, 18 second frame, 20a support, 20b sealing, 20b1-b4 lip, developer storage unit 25, developer storage chamber 26

Claims (10)

A frame provided with a developer storage chamber for storing the developer, and an opening for discharging the developer from the developer storage chamber;
A sealing unit provided inside the frame body,
A support portion rotatable in a first direction;
A sealing portion that is attached to the support portion and seals the opening by being compressed by the frame and the support portion, and includes a projection including a first portion and a second portion, A sealing portion configured so that the protruding portion can abut on the frame at a peripheral portion of the opening;
A sealing unit capable of shifting from a first state in which the sealing portion seals the opening to a second state in which the opening is opened,
With
When the sealing unit is in the first state, with respect to the first direction, the first portion abuts on the frame at a downstream side of the opening, and a root of the first portion. From the upstream toward the tip, it is inclined in a direction from the upstream side of the opening to the downstream side of the opening, the second portion abuts on the frame body on the upstream side of the opening, and the second portion Inclining in a direction from the downstream side of the opening toward the upstream side of the opening from the root of the portion toward the tip end,
When viewed in the direction of the rotation axis of the support, the length of the first portion from the root to the tip is greater than the thickness of the first portion,
The length of the second portion from the root to the tip is greater than the thickness of the second portion,
A developer accommodating unit, characterized in that: When the sealing unit is in the first state, with respect to the first direction, a part of an inner surface of the first portion abuts on the frame body downstream of the opening, and A part of the inner surface of the portion abuts on the frame body upstream of the opening,
The developer accommodating unit according to claim 1, wherein: A holding portion provided inside the frame,
A pressed portion provided in the sealing unit, and when the sealing unit is in the first state, a pressed portion that comes into contact with the pressing portion,
The developer accommodating unit according to claim 1, further comprising: The protrusion has elasticity,
When the sealing unit is in the first state, in a state where the shape of the first portion is deformed, the first portion abuts the frame on the downstream side of the opening, and the In a state where the shape of the second part is deformed, the second part abuts on the frame body on the upstream side of the opening,
When the sealing unit is in the second state, the pressed portion is separated from the pressing portion, the shape of the first portion returns to the original shape, and the shape of the second portion changes to the original shape. Return,
The developer accommodating unit according to claim 3, wherein: A concave shape is formed on a contact surface of the pressed portion with the pressing portion, and a convex shape is formed on a contact surface of the pressed portion with the pressed portion,
The developer accommodating unit according to claim 3 or 4, wherein The sealing unit has a recess provided inside the rotation radius of the pressed portion,
When the sealing unit is in the second state, a gap is formed between the inner surface of the concave portion and the pressing portion,
The developer accommodating unit according to any one of claims 3 to 5, wherein: The rigidity of the sealing portion is lower than the rigidity of the support portion,
The developer accommodating unit according to any one of claims 1 to 6, wherein: The support portion, the sealing portion and the protruding portion are integrally formed,
The developer accommodating unit according to any one of claims 1 to 7, wherein: A process cartridge detachably provided in a main body of an image forming apparatus that performs image formation,
A developer accommodating unit according to any one of claims 1 to 8,
An image carrier for carrying a developer image,
A process cartridge comprising: An image forming apparatus that performs image formation,
A developer accommodating unit according to any one of claims 1 to 8,
An image carrier for carrying a developer image,
A transfer unit for transferring the developer image carried on the image carrier to a recording material,
An image forming apparatus comprising:

Images