JP6257727B2 - Developer container - Google Patents

Description

The present invention relates to a removable developer container to the developer supply device. The developer accommodating container, for example, a copying machine, a facsimile machine, a printer, and may be used in an image forming apparatus such as a complex machine having a plurality of these functions.

  Conventionally, a fine powder developer is used in an image forming apparatus such as an electrophotographic copying machine. Such an image forming apparatus is configured to replenish the developer that is consumed in the image formation from the developer replenishing container.

  An example of such a conventional developer supply container is disclosed in Patent Document 1.

  The apparatus described in Patent Document 1 employs a system in which the developer is discharged using a bellows pump provided in the developer supply container. As a specific method, the developer is fluidized by taking air into the developer supply container by extending the bellows pump so that the pressure in the developer supply container is lower than the atmospheric pressure. Furthermore, by contracting the bellows pump so that the pressure inside the developer supply container is higher than the atmospheric pressure, the developer is pushed out and discharged due to the pressure difference inside and outside the developer supply container. By alternately repeating these two steps, the developer is stably discharged.

JP 2010-256894 A

  As described above, in the apparatus described in Patent Document 1, it is possible to stably discharge the developer from the developer supply container. However, in order to realize further image stability of the image forming apparatus, the developer supply is performed. Higher replenishment accuracy than ever is required for containers.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a developer supply container having higher developer supply accuracy from the developer supply container to the image forming apparatus.

To achieve the above object, the present invention provides a developer container detachably mountable to developer supplying apparatus, for discharging a developer accommodating portion for accommodating the developer, a developer contained in the developer containing portion A discharge part, a storage part that allows communication between the inside of the developer container and the discharge port, and stores the developer discharged through the discharge port, and at least a storage part for discharging the developer from the storage part And a rotatable rotating member provided opposite to the storage part, and the rotating member is partly viewed from the direction of the rotation axis of the rotating member. A first partition wall having an internal space and rotating about the rotation axis, and a periphery of the first partition wall so as to be able to communicate with the internal space of the first partition wall. A first opening provided on a surface, and the first partition wall A first side opening that is provided on a side wall on the amplifier portion side and communicates with the internal space of the first partition wall, and is provided so as to separate a part of the space when viewed from the direction of the rotation axis. A second partition wall that rotates about the rotation axis, and a second opening provided in the peripheral surface of the second partition wall so as to be able to communicate with the internal space of the second partition wall; A second side surface opening provided on a side wall of the second partition wall portion on the pump portion side and communicating with the internal space of the second partition wall portion; and the first partition wall portion and the second partition wall in the rotation direction of the rotating member. A transport unit that transports the developer to a space between the partition walls, and the first partition wall and the second partition wall are disposed at positions facing the storage unit. .

According to the present invention, a developer container, it is possible to discharge the developer in a high replenishing accuracy, the image forming apparatus, it is possible to provide a developer container having a more stable dischargeability .

1 is a cross-sectional view illustrating an overall configuration of an image forming apparatus. (A) is a partial cross-sectional view of the developer supply device, (b) is a perspective view of the mounting portion, and (c) is a cross-sectional view of the mounting portion. It is an expanded sectional view showing a developer supply container and a developer supply device. 6 is a flowchart illustrating a flow of developer replenishment. It is an expanded sectional view showing a modification of a developer supply device. (A) is a perspective view showing a developer supply container according to the first embodiment, (b) is a partially enlarged view showing a state around a discharge port, and (c) is a developer supply container attached to a mounting portion of a developer supply device. It is a front view which shows the mounted state. (A) is a cross-sectional perspective view of the developer supply container, (b) is a partial cross-sectional view in a state where the pump part is fully extended in use, and (c) is a part in which the pump part is fully contracted in use. It is sectional drawing. (A) is a perspective view of the braid | blade used with the apparatus which measures fluid energy, (b) is a schematic diagram of an apparatus. It is the graph which showed the relationship between the diameter of a discharge port, and discharge amount. It is the graph which showed the relationship between the filling amount in a container, and discharge | emission amount. (A) is a partial view of a state in which the pump unit is fully extended in use, (b) is a partial view of a state in which the pump is fully contracted in use, and (c) is a partial view of the pump unit. FIG. 6 is a development view showing a cam groove shape of a developer supply container. It is a figure which shows transition of the internal pressure of a developer supply container. FIG. 6 is a development view illustrating an example of a cam groove shape of a developer supply container. FIG. 6 is a development view illustrating an example of a cam groove shape of a developer supply container. FIG. 6 is a development view illustrating an example of a cam groove shape of a developer supply container. FIG. 6 is a development view illustrating an example of a cam groove shape of a developer supply container. FIG. 6 is a development view illustrating an example of a cam groove shape of a developer supply container. (A) is a perspective view of the whole conveyance member of Example 1, (b) is a side view of a conveyance member. It is sectional drawing of the discharge part at the time of the operation | movement stop process of the pump part in Example 1. FIG. FIG. 3 is a cross-sectional view of a discharge part during intake in Example 1. FIG. 3 is a cross-sectional view of a discharge unit during exhaust in Example 1. FIG. 4 is a cross-sectional view of a discharge unit after the developer is discharged in Example 1. It is a cross-sectional perspective view of a developer supply container of a comparative example. FIG. 6 is a cross-sectional perspective view showing a modified example in the first embodiment. 6 is a partial cross-sectional perspective view of a developer supply container in Embodiment 2. FIG. (A) is a perspective view of the whole conveyance member in Example 2, (b) is a fragmentary sectional perspective view of a conveyance member. (A) (b) is sectional drawing of the discharge part at the time of the exhaust_gas | exhaustion in Example 2. FIG.

  Hereinafter, the developer supply container and the developer supply system according to the present invention will be described in detail. In the following description, unless otherwise specified, various configurations of the developer supply container can be replaced with other known configurations having similar functions within the scope of the inventive concept. That is, unless otherwise specified, there is no intention to limit the configuration of the developer supply container described in the examples described later.

[Example 1]
First, the basic configuration of the image forming apparatus will be described, and then the developer supply system mounted on the image forming apparatus, that is, the configuration of the developer supply apparatus and the developer supply container will be described in order.

(Image forming device)
As an example of an image forming apparatus equipped with a developer replenishing device in which a developer replenishing container (so-called toner cartridge) is detachably mounted (removable), a copying machine (electrophotographic image forming apparatus) adopting an electrophotographic system is used. ) Will be described with reference to FIG.

  In the figure, reference numeral 100 denotes a copying machine main body (hereinafter referred to as an image forming apparatus main body or an apparatus main body). A document 101 is placed on the document glass 102. An optical latent image is formed by forming an optical image corresponding to the image information of the original on an electrophotographic photosensitive member 104 (hereinafter referred to as a photosensitive member) by a plurality of mirrors M and lenses Ln of the optical unit 103. To do. This electrostatic latent image is visualized by a dry developing device (one component developing device) 201a using toner (one component magnetic toner) as a developer (dry powder).

  In this example, an example in which a one-component magnetic toner is used as a developer to be replenished from the developer replenishing container 1 will be described. However, the configuration is not limited to such an example, and may be configured as described later.

  Specifically, when a one-component developing device that performs development using one-component nonmagnetic toner is used, the one-component nonmagnetic toner is supplied as a developer. In addition, when a two-component developer that performs development using a two-component developer in which a magnetic carrier and a non-magnetic toner are mixed is used, the non-magnetic toner is replenished as the developer. In this case, the developer may be replenished together with the magnetic carrier as well as the non-magnetic toner.

  Reference numerals 105 to 108 denote cassettes for storing recording media (hereinafter also referred to as “sheets”) S. Among the sheets S stacked in these cassettes 105 to 108, an optimum cassette is selected based on information input by an operator (user) from the liquid crystal operation unit of the copying machine or the sheet size of the original 101. Here, the recording medium is not limited to paper, and can be appropriately used and selected, for example, an OHP sheet.

  Then, one sheet S conveyed by the feeding / separating devices 105 </ b> A to 108 </ b> A is conveyed to the registration roller 110 via the conveying unit 109, and the rotation of the photosensitive member 104 and the scanning timing of the optical unit 103 are synchronized. Then transport.

  Reference numeral 111 denotes a transfer charger, and reference numeral 112 denotes a separation charger. Here, the image formed by the developer formed on the photosensitive member 104 is transferred to the sheet S by the transfer charger 111. Then, the sheet S to which the developer image (toner image) has been transferred is separated from the photoreceptor 104 by the separation charger 112.

  Thereafter, the sheet S conveyed by the conveying unit 113 is fixed on the developer image on the sheet by heat and pressure in the fixing unit 114, and then passes through the discharge reversing unit 115 in the case of single-sided copying. The paper is discharged to the discharge tray 117 by the roller 116.

  In the case of duplex copying, the sheet S passes through the discharge reversing unit 115 and is once discharged out of the apparatus by the discharge roller 116. Thereafter, the trailing edge of the sheet S passes through the flapper 118, and is controlled by the flapper 118 at the timing when it is still nipped by the discharge roller 116, and is reversely rotated to be conveyed into the apparatus again. . Further, after being conveyed to the registration roller 110 via the re-feed conveyance units 119 and 120, the sheet is discharged to the discharge tray 117 along the same path as in the case of single-sided copying.

  In the apparatus main body 100 having the above-described configuration, an image forming process device such as a developing unit 201a as a developing unit, a cleaner unit 202 as a cleaning unit, and a primary charger 203 as a charging unit is installed around the photosensitive member 104. . The developing device 201 a develops the developer by attaching the developer to the electrostatic latent image formed on the photosensitive member 104 by the optical unit 103 based on the image information of the document 101. The primary charger 203 is for uniformly charging the surface of the photoconductor in order to form a desired electrostatic image on the photoconductor 104. The cleaner unit 202 is for removing the developer remaining on the photosensitive member 104.

(Developer supply device)
Next, a developer replenishing device 201 that is a component of the developer replenishing system will be described with reference to FIGS. 2A is a partial cross-sectional view of the developer supply device 201, FIG. 2B is a perspective view of the mounting portion 10 to which the developer supply container 1 is mounted, and FIG. A cross-sectional view is shown. FIG. 3 shows a partially enlarged cross-sectional view of the control system and the developer supply container 1 and the developer supply device 201. FIG. 4 is a flowchart for explaining the flow of developer replenishment by the control system.

  As shown in FIG. 1, the developer supply device 201 includes a mounting portion (mounting space) 10 in which the developer supply container 1 is detachably mounted (detachable), and the developer discharged from the developer supply container 1. A hopper 10a for temporarily storing the toner, and a developing device 201a. As shown in FIG. 2C, the developer supply container 1 is configured to be mounted in the arrow M direction with respect to the mounting portion 10. That is, the developer supply container 1 is mounted on the mounting portion 10 so that the longitudinal direction (rotation axis direction) thereof substantially coincides with the arrow M direction. This arrow M direction is substantially parallel to an arrow X direction in FIG. Further, the direction in which the developer supply container 1 is removed from the mounting portion 10 is opposite to the arrow M direction.

  As shown in FIGS. 1 and 2A, the developing device 201a includes a developing roller 201f, a stirring member 201c, and feeding members 201d and 201e. The developer supplied from the developer supply container 1 is stirred by the stirring member 201c, sent to the developing roller 201f by the feeding members 201d and 201e, and supplied to the photosensitive member 104 by the developing roller 201f.

  The developing roller 201f has a leakage prevention sheet 201h disposed in contact with the developing roller 201f in order to prevent leakage of the developer between the developing blade 201g that regulates the developer coating amount on the roller and the developing device 201a. Is provided.

  Further, as shown in FIG. 2B, the mounting portion 10 comes into contact with the flange portion 4 (see FIG. 6) of the developer supply container 1 when the developer supply container 1 is mounted. A rotation restricting portion (holding mechanism) 11 for restricting the movement of 4 in the rotation direction is provided.

  Further, when the developer supply container 1 is mounted, the mounting portion 10 communicates with a discharge port (discharge hole) 4a (see FIG. 6) of the developer supply container 1 described later and discharges from the developer supply container 1. A developer receiving port (developer receiving hole) 13 for receiving the developed developer. Then, the developer is supplied from the discharge port 4 a of the developer supply container 1 to the developing device 201 a through the developer receiving port 13. In the present embodiment, the diameter φ of the developer receiving port 13 is set to about 3 mm as a fine port (pinhole) for the purpose of preventing contamination by the developer in the mounting portion 10 as much as possible. Yes. The diameter of the developer receiving port may be any diameter that allows the developer to be discharged from the discharge port 4a.

  Further, as shown in FIG. 3, the hopper 10a includes a conveying screw 10b for conveying the developer to the developing device 201a, an opening 10c communicating with the developing device 201a, and a developer accommodated in the hopper 10a. A developer sensor 10d for detecting the amount is provided.

  Furthermore, as shown in FIGS. 2B and 2C, the mounting portion 10 has a drive gear 300 that functions as a drive mechanism (drive portion). The driving gear 300 receives a rotational driving force from a driving motor 500 (not shown) via a driving gear train, and applies the rotational driving force to the developer supply container 1 set in the mounting portion 10. It has a function.

  Further, as shown in FIG. 3, the drive motor 500 is configured such that its operation is controlled by a control device (CPU) 600. As shown in FIG. 3, the control device 600 is configured to control the operation of the drive motor 500 based on the developer remaining amount information input from the developer sensor 10d.

  In this example, the drive gear 300 is set to rotate only in one direction in order to simplify the control of the drive motor 500. That is, the control device 600 is configured to control only on (operation) / off (non-operation) of the drive motor 500. Accordingly, the developer replenishing device 201 is compared with a configuration in which a reversal driving force obtained by periodically reversing the drive motor 500 (drive gear 300) in the forward direction and the reverse direction is applied to the developer replenishment container 1. The drive mechanism can be simplified.

(How to install / remove developer supply container)
Next, a method for loading / removing the developer supply container 1 will be described.

  First, the operator opens the replacement cover, and inserts and mounts the developer supply container 1 into the mounting portion 10 of the developer supply device 201. With this mounting operation, the flange portion 4 of the developer supply container 1 is held and fixed to the developer supply device 201.

  Thereafter, the mounting process is completed when the operator closes the replacement cover. Thereafter, the control device 600 controls the drive motor 500 to rotate the drive gear 300 at an appropriate timing.

  On the other hand, when the developer in the developer supply container 1 becomes empty, the operator opens the replacement cover and takes out the developer supply container 1 from the mounting portion 10. Then, a new developer supply container 1 prepared in advance is inserted and mounted in the mounting portion 10 and the replacement cover is closed, whereby the replacement operation from taking out the developer supply container 1 to remounting is completed.

(Developer supply control by developer supply device)
Next, the developer supply control by the developer supply device 201 will be described based on the flowchart of FIG. This developer replenishment control is executed by controlling various devices by a control device (CPU) 600.

  In this example, the control device 600 controls whether the drive motor 500 is activated or deactivated according to the output of the developer sensor 10d, so that a predetermined amount or more of developer is not accommodated in the hopper 10a. Yes.

  Specifically, first, the developer sensor 10d checks the amount of developer contained in the hopper 10a (S100). When it is determined that the developer storage amount detected by the developer sensor 10d is less than a predetermined amount, that is, when no developer is detected by the developer sensor 10d, the drive motor 500 is driven and fixed. The developer replenishment operation is executed for a time (S101).

  As a result of the developer replenishment operation, when it is determined that the developer storage amount detected by the developer sensor 10d has reached a predetermined amount, that is, when the developer is detected by the developer sensor 10d, the drive motor 500 Is turned off, and the developer supply operation is stopped (S102). By stopping the replenishment operation, a series of developer replenishment steps is completed.

  Such a developer replenishing step is configured to be repeatedly executed when the developer is consumed in association with image formation and the developer storage amount in the hopper 10a becomes less than a predetermined amount.

  As described above, the developer discharged from the developer supply container 1 may be temporarily stored in the hopper 10a and then supplied to the developing device 201a. In this example, the following development is performed. The agent supply device 201 is configured.

  Specifically, as shown in FIG. 5, the hopper 10a described above is omitted, and the developer is directly supplied from the developer supply container 1 to the developing device 201a. FIG. 5 shows an example in which a two-component developing device 800 is used as the developer supply device 201. The developing device 800 has a stirring chamber for supplying the developer and a developing chamber for supplying the developer to the developing sleeve 800a, and the developer transport directions are opposite to each other in the stirring chamber and the developing chamber. A stirring screw 800b is installed. The stirring chamber and the developing chamber communicate with each other at both ends in the longitudinal direction, and the two-component developer is circulated and conveyed between these two chambers. The stirring chamber is provided with a magnetic sensor 800c for detecting the toner concentration in the developer, and the control device 600 controls the operation of the drive motor 500 based on the detection result of the magnetic sensor 800c. Yes. In this configuration, the developer replenished from the developer replenishing container is nonmagnetic toner, or nonmagnetic toner and magnetic carrier.

  In this example, as will be described later, the developer in the developer supply container 1 is hardly discharged from the discharge port 4a only by the gravitational action, and the developer is discharged by a variable volume operation by the pump unit 3a. The variation of can be suppressed. Therefore, the hopper 10a can be omitted, and even in the example shown in FIG. 5, the developer can be stably supplied to the developing chamber.

(Developer supply container)
Next, the configuration of the developer supply container 1, which is a component of the developer supply system, will be described with reference to FIGS. 6A is an overall perspective view of the developer supply container 1, FIG. 6B is a partially enlarged view around the discharge port 4a of the developer supply container 1, and FIG. 6C is a developer supply container. 1 is a front view showing a state where 1 is mounted on a mounting portion 10; FIG. 7A is a cross-sectional perspective view of the developer supply container, FIG. 7B is a partial cross-sectional view in a state where the pump portion is extended to the maximum extent for use, and FIG. It is a fragmentary sectional view of the state contracted.

  As shown in FIG. 6A, the developer supply container 1 has a developer storage portion 2 (also referred to as a container main body) that is formed in a hollow cylindrical shape and has an internal space for storing the developer therein. Yes. In this example, the cylindrical portion 2k, the discharge portion 4c (see FIG. 5), and the pump portion 3a (see FIG. 5) function as the developer accommodating portion 2. Further, the developer supply container 1 has a flange portion 4 (also referred to as a non-rotating portion) on one end side in the longitudinal direction (developer transport direction) of the developer accommodating portion 2. The cylindrical portion 2k is configured to be rotatable relative to the flange portion 4. The cross-sectional shape of the cylindrical portion 2k may be a non-circular shape as long as it does not affect the rotational operation in the developer supply process. For example, an elliptical shape or a polygonal shape may be employed.

  In this example, as shown in FIG. 7B, the overall length L1 of the cylindrical portion 2k functioning as the developer storage chamber is set to about 460 mm, and the outer diameter R1 is set to about 60 mm. Further, the length L2 of the region where the discharge portion 4c functioning as the developer discharge chamber is installed is about 21 mm, and the total length L3 of the pump portion 3a (when the pump member 3a is in the most extended range in use) is As shown in FIG. 7C, about 29 mm, the total length L4 of the pump portion 3a (when in the most contracted range in use) is about 24 mm.

  In this example, as shown in FIGS. 6 and 7, the cylindrical portion 2k and the discharge portion 4c are arranged in the horizontal direction when the developer supply container 1 is mounted on the developer supply device 201. ing. That is, the cylindrical portion 2k has a structure in which the horizontal length is sufficiently longer than the vertical length, and the horizontal direction side is connected to the discharge portion 4c. Accordingly, when the developer replenishing container 1 is mounted on the developer replenishing device 201, the upper side of the discharge port 4a, which will be described later, is compared to the case where the cylindrical portion 2k is positioned vertically above the discharge portion 4c. The amount of developer present in the toner can be reduced. Therefore, the developer in the vicinity of the discharge port 4a is not easily consolidated, and the intake / exhaust operation can be performed smoothly.

(Material of developer supply container)
In this example, as will be described later, the developer is discharged from the discharge port 4a by changing the volume in the developer supply container 1 by the pump unit 3a. Therefore, it is preferable to employ a material having a rigidity that does not collapse or swell greatly with respect to the change in volume as the material of the developer supply container 1.

  In this example, the developer supply container 1 communicates with the outside only through the discharge port 4a, and is configured to be sealed from the outside except for the discharge port 4a. In other words, since the configuration in which the developer is discharged from the discharge port 4a by reducing and increasing the volume of the developer supply container 1 by the pump unit 3a is adopted, the airtightness to the extent that stable discharge performance can be maintained. Desired.

  Therefore, in this example, the material of the developer accommodating portion 2 and the discharge portion 4c is made of polystyrene resin, and the material of the pump portion 3a is made of polypropylene resin.

  In addition, as for the material used, the developer container 2 and the discharge part 4c may be other materials such as ABS (acrylonitrile / butadiene / styrene copolymer), polyester, polyethylene, polypropylene, etc. It is possible to use a resin. Further, it may be made of metal.

  The material of the pump unit 3a may be any material that can exhibit an expansion / contraction function and can change the volume of the developer supply container 1 by changing the volume. For example, ABS (acrylonitrile / butadiene / styrene copolymer), polystyrene, polyester, polyethylene or the like may be formed thin. It is also possible to use rubber or other elastic materials.

  In addition, if each of the pump part 3a, the developer accommodating part 2, and the discharge part 4c satisfies the functions described above by adjusting the thickness of the resin material, etc., each is made of the same material, for example, an injection molding method or What was integrally shape | molded using the blow molding method etc. may be used.

  Hereinafter, the configuration of the flange portion 4, the cylindrical portion 2k, the pump portion 3a, the drive receiving mechanism 2d, and the drive conversion mechanism 2e (cam groove) in the developer supply container will be described in detail in order.

(Flange part)
As shown in FIGS. 7A and 7B, the flange portion 4 has a hollow discharge portion (developer discharge chamber) 4c for temporarily storing the developer conveyed from the cylindrical portion 2k. Is provided. At the bottom of the discharge portion 4c, a small discharge port 4a for allowing the developer to be discharged out of the developer supply container 1, that is, for supplying the developer to the developer supply device 201 is formed. In addition, a communication path 4d is provided above the discharge port 4a. The communication path 4d can store a predetermined amount of developer before discharge that connects the discharge port 4a and the inside of the developer supply container 1. This communication path also has a function of a developer reservoir that can store a predetermined amount of developer before being discharged. The size of the discharge port 4a will be described later.

  Further, the flange portion 4 is provided with a shutter 4b for opening and closing the discharge port 4a. The shutter 4b is configured to abut against a butting portion 21 (see FIG. 2B) provided in the mounting portion 10 in accordance with the mounting operation of the developer supply container 1 to the mounting portion 10. Accordingly, the shutter 4b is moved in the direction of the axis of rotation of the cylindrical portion 2k (opposite to the direction of arrow M in FIG. 2C) in accordance with the mounting operation of the developer supply container 1 to the mounting portion 10. Slide relative to. As a result, the discharge port 4a is exposed from the shutter 4b and the opening operation is completed.

  At this time, the discharge port 4a is in communication with each other because the position coincides with the developer receiving port 13 of the mounting portion 10, and the developer supply from the developer supply container 1 is possible.

  The flange portion 4 is configured to be substantially immovable when the developer supply container 1 is mounted on the mounting portion 10 of the developer supply device 201.

Specifically, the rotation restricting portion 11 shown in FIG. 2B is provided so that the flange portion 4 does not rotate in the rotation direction of the cylindrical portion 2k. In the state where it is mounted on the agent replenishing device 201, the discharge portion 4c provided on the flange portion 4 is also substantially prevented from rotating in the rotation direction of the cylindrical portion 2k (allowing movement of looseness is allowed). ).

  On the other hand, the cylindrical portion 2k is configured to rotate in the developer supply process without being restricted by the developer supply device 201 in the rotation direction.

  Further, as shown in FIG. 7, a plate-like conveyance member 6 is provided for conveying the developer conveyed from the cylindrical portion 2k by the spiral convex portion (conveyance protrusion) 2c to the discharge portion 4c. ing. The conveying member 6 is provided so as to divide a part of the developer accommodating portion 2 into two substantially, and is configured to rotate integrally with the cylindrical portion 2k. The conveying member 6 is provided with a plurality of inclined ribs 6a inclined on the discharge portion 4c side with respect to the rotational axis direction of the cylindrical portion 2k on both surfaces thereof. In the present configuration, a restricting portion 7 is provided at the end of the conveying member 6. The detailed description of the restricting unit 7 will be described later.

  With the above configuration, the developer transported by the transport protrusion 2c is scraped up from the lower side in the vertical direction by the plate-shaped transport member 6 in conjunction with the rotation of the cylindrical portion 2k. Thereafter, as the rotation of the cylindrical portion 2k progresses, it slides down on the surface of the conveying member 6 due to gravity and is eventually delivered to the discharge portion 4c side by the inclined rib 6a. In this configuration, the inclined ribs 6a are provided on both surfaces of the conveying member 6 so that the developer is sent to the discharge portion 4c every time the cylindrical portion 2k makes a half turn.

(About the outlet of the flange)
In this example, the discharge port 4a of the developer supply container 1 is set to such a size that the developer supply container 1 is not sufficiently discharged only by the gravitational action when the developer supply container 1 is in a posture to supply the developer to the developer supply device 201. doing. That is, the opening size of the discharge port 4a is set to be small enough that the developer is not sufficiently discharged from the developer supply container by the gravitational action alone (also referred to as a fine port (pinhole)). In other words, the size of the opening is set so that the discharge port 4a is substantially closed with the developer. Thereby, the following effects can be expected.

  (1) The developer is difficult to leak from the discharge port 4a.

  (2) Excessive developer discharge when the discharge port 4a is opened can be suppressed.

  (3) The discharge of the developer can be made to depend predominantly on the exhaust operation by the pump unit 3a.

  Therefore, the present inventors conducted a verification experiment as to how large the discharge port 4a that is not sufficiently discharged only by the gravitational action should be set. Hereinafter, the verification experiment (measurement method) and the determination criteria will be described below.

Prepare a rectangular parallelepiped container with a predetermined volume with a discharge port (circular shape) formed in the center of the bottom, and after filling the container with 200 g of developer, shake the container well with the filling port sealed and the discharge port closed. Thoroughly remove the developer. This rectangular parallelepiped container has a volume of about 1000 cm ³ and a size of 90 mm long × 92 mm wide × 120 mm high.

  Thereafter, the discharge port is opened with the discharge port directed vertically downward as soon as possible, and the amount of the developer discharged from the discharge port is measured. At this time, this rectangular parallelepiped container is completely sealed except for the discharge port. The verification experiment was performed in an environment of a temperature of 24 ° C. and a relative humidity of 55%.

  In the above procedure, the amount of discharge is measured while changing the type of developer and the size of the discharge port. In this example, when the amount of the discharged developer is 2 g or less, the amount is negligible, and it is determined that the discharge port has a size that cannot be discharged sufficiently only by the gravitational action.

  Table 1 shows the developers used in the verification experiment. The type of developer is a mixture of a one-component magnetic toner, a two-component nonmagnetic toner used in a two-component developer, and a two-component nonmagnetic toner used in a two-component developer and a magnetic carrier.

  In addition to the angle of repose indicating the fluidity, the physical properties representing the characteristics of these developers include the fluidity indicating the ease of unraveling of the developer layer by a powder fluidity analyzer (Powder Rheometer FT4 manufactured by Freeman Technology). The energy was measured.

  A method for measuring the fluidity energy will be described with reference to FIG. Here, FIG. 8 is a schematic diagram of an apparatus for measuring fluidity energy.

  The principle of this powder fluidity analyzer is to measure the fluidity energy necessary for moving the blade in the powder sample and moving the blade in the powder. Since the blade is a propeller type and moves in the direction of the rotation axis at the same time as rotating, the tip of the blade draws a spiral.

  As the propeller blade 54 (hereinafter referred to as a blade), a SUS blade (model number: C210) having a diameter of 48 mm and smoothly twisted counterclockwise was used. More specifically, a rotation axis exists in the direction normal to the rotation surface of the blade plate at the center of the blade plate of 48 mm × 10 mm, and the twist angle of both outermost edge portions (parts 24 mm from the rotation axis) of the blade plate is 70. The twist angle of a portion 12 mm from the rotation axis is 35 °.

  The fluidity energy means that the blade 54 rotating spirally as described above enters the powder layer, and the sum of the rotational torque and vertical load obtained when the blade moves in the powder layer is integrated over time. Refers to the total energy obtained. This value represents the ease of unraveling of the developer powder layer, which means that it is difficult to unravel when the fluidity energy is large, and is easy to unravel when the fluidity energy is small.

  In this measurement, as shown in FIG. 8, each developer T is 70 mm in powder level height (FIG. 8) in a cylindrical container 53 (volume 200 cc, L1 = 50 mm in FIG. 8) which is a standard part of this apparatus. L2). The filling amount is adjusted according to the bulk density to be measured. Further, a φ54 mm blade 54, which is a standard part, is penetrated into the powder layer, and the energy obtained between the penetration depths of 10 to 30 mm is displayed.

  Setting conditions at the time of measurement include the rotational speed of the blade 54 (tip speed, the peripheral speed of the outermost edge of the blade) of 60 mm / s, and the blade entrance speed in the vertical direction to the powder layer, The speed at which the angle θ (helix angle, hereinafter referred to as the angle formed) formed by the locus drawn by the outermost edge 54 and the surface of the powder layer is 10 °. The approach speed in the vertical direction into the powder layer is 11 mm / s (blade approach speed in the vertical direction into the powder layer = blade rotation speed × tan (angle formed × π / 180)). This measurement was also performed in an environment at a temperature of 24 ° C. and a relative humidity of 55%.

The bulk density of the developer when measuring the fluidity energy of the developer is close to the bulk density in the experiment for verifying the relationship between the developer discharge amount and the size of the discharge port, and the change in the bulk density is The bulk density that can be measured with little stability is adjusted to 0.5 g / cm ³ .

  FIG. 9 shows the result of a verification experiment performed on the developer (Table 1) having the fluidity energy thus measured. FIG. 9 is a graph showing the relationship between the diameter of the discharge port and the discharge amount for each type of developer.

From the verification results shown in FIG. 9, if the developer φ is less than or equal to the diameter φ of the discharge port of 4 mm (opening area is 12.6 mm ² : the circumference is calculated by 3.14, the same applies hereinafter). It was confirmed that the amount discharged from the outlet was 2 g or less. It was confirmed that when the diameter φ of the discharge port is larger than 4 mm, the discharge amount increases rapidly with any developer.

That is, the fluidity energy (bulk density is 0.5 g / cm ³ ) of the developer is 4.3 × 10 ⁻⁴ (kg · m ² / s ² (J)) or more and 4.14 × 10 ⁻³ (kg When m ² / s ² (J)) or less, the diameter φ of the discharge port may be 4 mm or less (opening area is 12.6 (mm ² )) or less.

  Moreover, the bulk density of the developer is measured in a state where the developer is sufficiently fluidized and fluidized in this verification experiment, which is more than the state assumed in a normal use environment (the state in which it is left unattended). Measurement is performed under the condition that the bulk density is low and the discharge is easier.

  Next, using the developer A having the largest discharge amount from the result of FIG. 9, the diameter φ of the discharge port is fixed to 4 mm, the filling amount in the container is changed to 30 to 300 g, and the same verification experiment is performed. Went. The verification result is shown in FIG. From the verification results of FIG. 10, it was confirmed that even when the developer filling amount was changed, the discharge amount from the discharge port was hardly changed.

From the above results, by setting the discharge port to φ4 mm (area 12.6 mm ² ) or less, regardless of the type of developer and the bulk density state, the discharge port is at the bottom (replenishment to the developer supply device 201) Assuming the posture), it was confirmed that gravity was not discharged sufficiently from the discharge port alone.

  On the other hand, as the lower limit value of the size of the discharge port 4a, at least the developer to be replenished from the developer replenishing container 1 (1 component magnetic toner, 1 component nonmagnetic toner, 2 component nonmagnetic toner, 2 component magnetic carrier) is at least. It is preferable to set the value so that it can pass through. That is, it is preferable that the outlet be larger than the particle size of the developer contained in the developer supply container 1 (volume average particle size for toner, number average particle size for carrier). For example, if the developer for replenishment contains a two-component non-magnetic toner and a two-component magnetic carrier, the larger particle size, that is, a discharge port larger than the number average particle size of the two-component magnetic carrier Is preferred.

Specifically, when the developer to be replenished includes a two-component non-magnetic toner (volume average particle size is 5.5 μm) and a two-component magnetic carrier (number average particle size is 40 μm), the outlet 4a The diameter is preferably set to 0.05 mm (opening area 0.002 mm ² ) or more.

  However, if the size of the discharge port 4a is set close to the particle size of the developer, the energy required to discharge a desired amount from the developer supply container 1, that is, the pump unit 3a is operated. The energy required for this will increase. In addition, there may be restrictions in manufacturing the developer supply container 1. In order to mold the discharge port 4a in the resin part using the injection molding method, the durability of the mold part that forms the portion of the discharge port 4a becomes severe. From the above, the diameter φ of the discharge port 4a is preferably set to 0.5 mm or more.

In addition, in this example, although the shape of the discharge port 4a is circular, it is not limited to such a shape. That is, if the opening having an opening area of 12.6 mm ² or less is an opening area of a diameter corresponding to the case of 4 mm, square, rectangular, oval or the like shape that combines straight lines and curves, to be changed is there.

  However, when the opening area of the circular discharge port is the same, the circumferential length of the edge of the opening where the developer adheres and becomes dirty is the smallest compared to other shapes. Therefore, the amount of the developer that spreads in conjunction with the opening / closing operation of the shutter 4b is small, and it is difficult to get dirty. In addition, the circular discharge port has the lowest discharge resistance and the highest discharge performance. Accordingly, the shape of the discharge port 4a is more preferably a circular shape having the best balance between the discharge amount and the prevention of contamination.

From the above, the size of the discharge port 4a is preferably such that the discharge port 4a is vertically discharged downward (assuming a replenishment posture to the developer replenishing device 201) and is not sufficiently discharged only by gravity action. Specifically, the diameter φ of the discharge port 4a is preferably set in a range of 0.05 mm (opening area 0.002 mm ² ) or more and 4 mm (opening area 12.6 mm ² ) or less. Furthermore, the diameter φ of the discharge port 4a is, 0.5 mm to set the range of (the opening area 0.2 mm ²⁾ or more 4 mm (opening area 12.6 mm ²⁾ is more preferable. In this example, from the above viewpoint, the discharge port 4a is circular, and the diameter φ of the opening is set to 2 mm.

  In this example, the number of the discharge ports 4a is one, but the number is not limited to this, and a plurality of discharge ports 4a may be provided so that each opening area satisfies the above-described range of the opening area. Absent. For example, two discharge ports 4a having a diameter φ of 0.7 mm are provided for one developer receiving port 13 having a diameter φ of 3 mm. However, in this case, since the developer discharge amount (per unit time) tends to decrease, a configuration in which one discharge port 4a having a diameter φ of 2 mm is provided is more preferable.

(Cylindrical part)
Next, the cylindrical portion 2k functioning as a developer storage chamber will be described with reference to FIGS.

  As shown in FIGS. 6 and 7, the cylindrical portion 2 k has a discharge portion 4 c (discharge port 4 a) that functions as a developer discharge chamber on the inner surface of the cylindrical portion 2 k along with its rotation. A conveying protrusion 2c that protrudes in a spiral shape and functions as a conveying unit that conveys toward the surface is provided. The cylindrical portion 2k is formed by a blow molding method using the above-described resin.

  Note that when the volume of the developer supply container 1 is increased to increase the filling amount, a method of increasing the volume of the discharge unit 4c as the developer storage unit 2 in the height direction is conceivable. However, with such a configuration, the gravity effect on the developer near the discharge port 4a is further increased by the weight of the developer. As a result, the developer in the vicinity of the discharge port 4a is easily consolidated, which hinders intake / exhaust through the discharge port 4a. In this case, it is necessary to further increase the volume change amount of the pump unit 3a in order to release the developer that has been compacted by intake air from the discharge port 4a or to discharge the developer by exhaust gas. However, as a result, the driving force for driving the pump unit 3a also increases, and the load on the image forming apparatus main body 100 may become excessive.

  On the other hand, in the present example, the cylindrical portion 2k is horizontally arranged on the flange portion 4 and the filling amount is adjusted by the volume of the cylindrical portion 2k. The thickness of the developer layer on the discharge port 4a in 1 can be set thin. As a result, the developer is less likely to be consolidated by the gravitational action, and as a result, the developer can be discharged stably without imposing a load on the image forming apparatus main body 100.

  Further, as shown in FIGS. 7B and 7C, the cylindrical portion 2k is compressed with respect to the flange portion 4 in a state where the flange seal 5b of the ring-shaped seal member provided on the inner surface of the flange portion 4 is compressed. It is fixed so that it can rotate relative to the other.

  Thereby, the cylindrical portion 2k rotates while sliding with the flange seal 5b, so that the developer does not leak during rotation and the airtightness is maintained. In other words, air can be appropriately entered and exited through the discharge port 4a, and the volume of the developer supply container 1 can be changed to a desired state during supply.

(Pump part)
Next, a pump unit 3a (which can reciprocate) whose volume is variable with the reciprocation will be described with reference to FIG. Here, FIG. 7A is a cross-sectional perspective view of the developer supply container, FIG. 7B is a partial cross-sectional view in a state where the pump portion is fully extended for use, and FIG. 7C is used by the pump portion. It is a fragmentary sectional view of the state contracted to the maximum.

  The pump unit 3a of this example functions as an intake / exhaust mechanism that alternately performs intake and exhaust operations via the discharge port 4a. In other words, the pump unit 3a functions as an airflow generating mechanism that alternately and repeatedly generates an airflow that goes to the inside of the developer supply container through the discharge port 4a and an airflow that goes from the developer supply container to the outside.

  The pump part 3a is provided in the arrow X direction from the discharge part 4c, as shown in FIG. That is, the pump part 3a is provided so as not to rotate in the rotation direction of the cylindrical part 2k together with the discharge part 4c.

  Further, the pump unit 3a of the present example is configured to accommodate the developer therein. As will be described later, the developer storage space in the pump unit 3a plays a major role in fluidizing the developer during the intake operation.

In this example, as the pump portion 3a, a resin variable volume pump portion (bellows pump) whose volume is variable with reciprocation is adopted. Specifically, as shown in FIGS. 7A to 7C, a bellows-like pump is employed, and a plurality of “mountain folds” and “valley folds” are periodically and alternately formed. Yes. Therefore, the pump unit 3a can repeatedly perform compression and expansion alternately by the driving force received from the developer supply device 201. In this example, the volume change amount at the time of expansion and contraction of the pump unit 3a is set to 5 cm ³ (cc). L3 shown in FIG. 7B is about 29 mm, and L4 shown in FIG. 7C is about 24 mm. The outer diameter R2 of the pump part 3a is about 45 mm.

  By adopting such a pump unit 3a, the volume of the developer supply container 1 can be varied and can be alternately and repeatedly changed at a predetermined cycle. As a result, the developer in the discharge portion 4c can be efficiently discharged from the discharge port 4a having a small diameter (diameter of about 2 mm).

(Drive receiving mechanism)
Next, a description will be given of a drive receiving mechanism (drive receiving portion, driving force receiving portion) of the developer supply container 1 that receives from the developer supply device 201 a rotational driving force for rotating the cylindrical portion 2k provided with the transport protrusion 2c. To do.

  As shown in FIG. 6A, the developer supply container 1 has a drive receiving mechanism (drive receiving portion) that can be engaged (drive coupled) with a drive gear 300 (functioning as a drive mechanism) of the developer supply device 201. , A gear portion 2d that functions as a driving force receiving portion) is provided. The gear portion 2d is configured to be rotatable integrally with the cylindrical portion 2k.

  Accordingly, the rotational driving force input from the drive gear 300 to the gear portion 2d is transmitted to the pump portion 3a via the reciprocating member 3b shown in FIGS. 11 (a) and 11 (b). Specifically, a drive conversion mechanism will be described later. The bellows-like pump part 3a of this example is manufactured using a resin material having a strong resistance to twisting in the rotation direction within a range that does not hinder its expansion and contraction operation.

  In this example, the gear portion 2d is provided on the longitudinal direction (developer transport direction) side of the cylindrical portion 2k. However, the gear portion 2d is not limited to this example. For example, the longitudinal direction of the developer accommodating portion 2 is provided. You may provide in the other end side, ie, the last tail side. In this case, the drive gear 300 is installed at a corresponding position.

  In this example, a gear mechanism is used as a drive coupling mechanism between the drive receiving portion of the developer supply container 1 and the drive portion of the developer supply device 201. However, the present invention is not limited to this example. A known coupling mechanism may be used. Specifically, a non-circular concave portion is provided as a driving receiving portion, while a convex portion having a shape corresponding to the aforementioned concave portion is provided as a driving portion of the developer supply device 201, and these are driven and connected to each other. I do not care.

(Drive conversion mechanism)
Next, the drive conversion mechanism (drive conversion unit) of the developer supply container 1 will be described. In this example, a case where a cam mechanism is used as an example of the drive conversion mechanism will be described.

  The developer supply container 1 functions as a drive conversion mechanism (drive conversion unit) that converts a rotational driving force for rotating the cylindrical portion 2k received by the gear portion 2d into a force in a direction for reciprocating the pump portion 3a. A cam mechanism is provided.

  That is, in this example, the driving force for rotating the cylindrical portion 2k and the driving force for reciprocating the pump portion 3a by converting the rotational driving force received by the gear portion 2d into reciprocating power on the developer supply container 1 side. Is received by one drive receiving portion (gear portion 2d).

  As a result, the configuration of the drive input mechanism of the developer supply container 1 can be simplified as compared with the case where two drive receiving portions are separately provided in the developer supply container 1. Furthermore, since it is configured to be driven from one drive gear of the developer supply device 201, it is possible to contribute to simplification of the drive mechanism of the developer supply device 201.

  Here, FIG. 11A is a partial view of a state in which the pump portion 3a is extended to the maximum in use, FIG. 11B is a partial view of a state in which the pump portion 3a is maximally contracted in use, and FIG. c) is a partial view of the pump section. As shown in FIGS. 11 (a) and 11 (b), a reciprocating member 3b is used as a member interposed for converting the rotational driving force into the reciprocating power of the pump portion 3a. Specifically, the drive receiving portion (gear portion 2d) that receives the rotational drive from the drive gear 300 and the cam groove 2e provided with grooves on the entire circumference rotate. The cam groove 2e will be described later. In this cam groove 2e, a reciprocating member engaging projection 3c partially protruding from the reciprocating member 3b is engaged with the cam groove 2e. In this example, as shown in FIG. 11 (c), the reciprocating member 3b does not rotate in the direction of rotation of the cylindrical portion 2k (allows backlash), and the protection member rotation restricting portion. The rotation direction of the cylindrical portion 2k is regulated by 3f. Thus, by restricting the rotation direction, the reciprocating motion is restricted along the groove of the cam groove 2e (in the arrow X direction or the reverse direction in FIG. 7). Furthermore, a plurality of reciprocating member engaging protrusions 3c are provided to engage with the cam groove 2e. Specifically, the two reciprocating member engaging protrusions 3c are provided to face the outer peripheral surface of the cylindrical portion 2k at about 180 °.

  Here, the number of the reciprocating member engaging protrusions 3c may be at least one. However, a moment is generated in the drive conversion mechanism due to the drag force when the pump portion 3a is expanded and contracted, and there is a risk that smooth reciprocation will not be performed. Is preferred.

  That is, when the cam groove 2e is rotated by the rotational driving force input from the drive gear 300, the reciprocating member engaging protrusion 3c reciprocates along the cam groove 2e in the arrow X direction or in the opposite direction. The volume of the developer replenishing container 1 can be varied by alternately repeating the state in which the pump unit 3a is extended (FIG. 11A) and the state in which the pump unit 3a is contracted (FIG. 11B). Can do.

(Setting conditions of drive conversion mechanism)
In this example, in the drive conversion mechanism, the developer transport amount (per unit time) transported to the discharge unit 4c with the rotation of the cylindrical unit 2k is discharged from the discharge unit 4c to the developer supply device 201 by the action of the pump unit. The drive conversion is performed so as to be larger than the amount (per unit time).

  This is because when the developer discharging ability by the pump unit 3a is larger than the developer conveying ability by the conveying protrusion 2c to the discharging unit 4c, the amount of the developer present in the discharging unit 4c gradually decreases. Because it ends up. That is, it is to prevent the time required for supplying the developer from the developer supply container 1 to the developer supply device 201 from becoming long.

  In this example, the drive conversion mechanism performs drive conversion so that the pump unit 3a reciprocates a plurality of times while the cylindrical unit 2k rotates once. This is due to the following reasons.

  In the case of the configuration in which the cylindrical portion 2k is rotated in the developer supply device 201, it is preferable that the drive motor 500 is set to an output necessary for constantly rotating the cylindrical portion 2k. However, in order to reduce energy consumption in the image forming apparatus 100 as much as possible, it is preferable to reduce the output of the drive motor 500 as much as possible. Here, since the output required for the drive motor 500 is calculated from the rotational torque and the rotational speed of the cylindrical portion 2k, in order to reduce the output of the drive motor 500, the rotational speed of the cylindrical portion 2k is made as low as possible. It is preferable to set.

  However, in the case of this example, if the rotational speed of the cylindrical portion 2k is reduced, the number of operations of the pump portion 3a per unit time is reduced. Therefore, the amount of developer discharged from the developer supply container 1 (Per unit time) will decrease. In other words, the amount of developer discharged from the developer supply container 1 may be insufficient to satisfy the developer supply amount required from the image forming apparatus main body 100 in a short time.

  Therefore, if the volume change amount of the pump unit 3a is increased, the developer discharge amount per cycle of the pump unit 3a can be increased, so that the request from the image forming apparatus main body 100 can be met. Such a countermeasure has the following problems.

  That is, when the volume change amount of the pump unit 3a is increased, the peak value of the internal pressure (positive pressure) of the developer supply container 1 in the exhaust process increases, so that the load required to reciprocate the pump unit 3a increases. End up.

  For this reason, in this example, the pump portion 3a is operated for a plurality of cycles while the cylindrical portion 2k rotates once. As a result, the developer discharge amount per unit time can be reduced without increasing the volume change amount of the pump unit 3a as compared with the case where the pump unit 3a is operated only for one cycle while the cylindrical unit 2k rotates once. It becomes possible to increase. Then, the number of rotations of the cylindrical portion 2k can be reduced by the amount that the developer discharge amount can be increased.

  Accordingly, with the configuration as in this example, the drive motor 500 can be set to a smaller output, which can contribute to reduction of energy consumption in the image forming apparatus main body 100.

(Location of drive conversion mechanism)
In this example, as shown in FIG. 11, a drive conversion mechanism (a cam mechanism constituted by a reciprocating member engaging projection 3 c and a cam groove 2 e) is provided outside the developer accommodating portion 2. That is, the drive conversion mechanism is removed from the internal space of the cylindrical portion 2k, the pump portion 3a, and the discharge portion 4c so as not to come into contact with the developer accommodated in the cylindrical portion 2k, the pump portion 3a, and the discharge portion 4c. It is provided in a separated position.

  Thereby, the problem assumed when the drive conversion mechanism is provided in the internal space of the developer container 2 can be solved. In other words, due to the intrusion of the developer into the rubbing part of the drive conversion mechanism, heat and pressure are applied to the developer particles to soften and some particles stick together to form a large lump (coarse), It is possible to prevent the torque from being increased due to the developer biting into the conversion mechanism.

  Hereinafter, a developer replenishing step to the developer replenishing device 201 by the developer replenishing container 1 will be described.

(Developer replenishment process)
Next, the developer replenishing step by the pump unit 3a will be described with reference to FIGS. FIG. 11A is a partial view of a state in which the pump unit 3a is fully extended for use, FIG. 11B is a partial view of a state in which the pump unit 3a is fully contracted for use, and FIG. It is a fragmentary figure of the pump part 3a. FIG. 12 is a development view of the cam groove 2e in the above-described drive conversion mechanism (cam mechanism constituted by the reciprocating member engaging protrusion 3c and the cam groove 2e).

  In this example, as will be described later, an intake process (intake operation through the exhaust port 4a) and an exhaust process (exhaust operation through the exhaust port 4a) and an operation stop process (exhaust port) by non-operation of the pump unit are performed. 4a is not performed), and the drive conversion mechanism converts the rotational driving force into reciprocating power. Hereinafter, the intake process, the exhaust process, and the operation stop process will be described in detail in order.

(Intake process)
First, the intake process (intake operation through the discharge port 4a) will be described.

  The intake operation is performed by changing from the state shown in FIG. 11B where the pump unit 3a is contracted most to the state shown in FIG. 11A where the pump unit 3a is extended the most by the drive conversion mechanism (cam mechanism) described above. That is, with this intake operation, the volume of the portion (pump portion 3a, cylindrical portion 2k, discharge portion 4c) that can store the developer in the developer supply container 1 increases.

  At that time, the inside of the developer supply container 1 is substantially sealed except for the discharge port 4a, and the discharge port 4a is substantially closed with the developer T. Therefore, the internal pressure of the developer supply container 1 decreases as the volume of the portion of the developer supply container 1 that can store the developer T increases.

  At this time, the internal pressure of the developer supply container 1 becomes lower than the atmospheric pressure (external pressure). Therefore, the air outside the developer supply container 1 moves into the developer supply container 1 through the discharge port 4a due to a pressure difference between the inside and outside of the developer supply container 1.

  At that time, since air is taken in from the outside of the developer supply container 1 through the discharge port 4a, the developer T located in the vicinity of the discharge port 4a can be unwound (fluidized). Specifically, the bulk density can be reduced by including air in the developer located in the vicinity of the discharge port 4a, and the developer T can be fluidized appropriately.

  Further, at this time, since air is taken into the developer supply container 1 through the discharge port 4a, the internal pressure of the developer supply container 1 is close to the atmospheric pressure (outside air pressure) despite the increase in volume. Will change.

  In this way, by allowing the developer T to flow, the developer T can be smoothly discharged from the discharge port 4a without the developer T being clogged in the discharge port 4a during the exhaust operation described later. It becomes. Therefore, the amount (per unit time) of the developer T discharged from the discharge port 4a can be made almost constant over a long period of time.

  Note that because the intake operation is performed, the pump unit 3a is not limited to the most extended state from the most contracted state, and even if the pump unit 3a stops in the middle of the most extended state from the most contracted state, the development is performed. If the internal pressure change of the agent supply container 1 is performed, the intake operation is performed. That is, the intake step is a state where the reciprocating member engaging protrusion 3c is engaged with the cam groove 2h shown in FIG.

(Exhaust process)
Next, the exhaust process (exhaust operation through the exhaust port 4a) will be described.

  The exhaust operation is performed by changing from FIG. 11A in the state in which the pump portion 3a is extended to FIG. 11B in the state in which the pump portion 3a is contracted most. Specifically, the volume of the portion (pump portion 3a, cylindrical portion 2k, discharge portion 4c) that can store the developer in the developer supply container 1 is reduced along with this exhausting operation. At that time, the inside of the developer supply container 1 is substantially sealed except for the discharge port 4a, and the discharge port 4a is substantially closed with the developer T until the developer is discharged. Yes. Accordingly, the internal pressure of the developer supply container 1 increases as the volume of the portion of the developer supply container 1 that can store the developer T decreases.

  At this time, since the internal pressure of the developer supply container 1 becomes higher than the atmospheric pressure (external pressure), the developer T is pushed out from the discharge port 4a due to the pressure difference between the inside and outside of the developer supply container 1. That is, the developer T is discharged from the developer supply container 1 to the developer supply device 201.

  Since the air in the developer supply container 1 is also discharged together with the developer T, the internal pressure of the developer supply container 1 decreases.

  As described above, in this example, since the developer can be efficiently discharged using one reciprocating pump unit 3a, the mechanism required for the developer discharge can be simplified.

  Since the pumping operation is performed, the pump unit 3a is not limited to the most contracted state from the most extended state, and even if the pump unit 3a stops in the middle of the most contracted state from the most extended state, the development is performed. If the internal pressure change of the agent supply container 1 is performed, the exhaust operation is performed. That is, the exhaust process is a state where the reciprocating member engaging protrusion 3c is engaged with the cam groove 2g shown in FIG.

(Operation stop process)
Next, an operation stop process in which the pump unit 3a does not reciprocate will be described.

  In this example, as described above, the control device 600 controls the operation of the drive motor 500 based on the detection results of the magnetic sensor 800c and the developer sensor 10d. In this configuration, since the amount of developer discharged from the developer supply container directly affects the toner density, it is necessary to supply the developer amount required by the image forming apparatus from the developer supply container 1. At this time, in order to stabilize the amount of developer discharged from the developer replenishing container, it is desirable to perform a predetermined variable volume every time.

  For example, if the cam groove 2e is configured only by the exhaust process and the intake process, the motor drive is stopped during the exhaust process or the intake process. At that time, the cylinder part 2k rotates due to inertia even after the drive motor 500 stops rotating, and the pump part 3a continues to reciprocate in conjunction with the cylinder part 2k until the cylinder part 2k stops, and the exhaust process or the intake process is performed. It becomes. The distance that the cylindrical portion 2k rotates due to inertia depends on the rotational speed of the cylindrical portion 2k. Furthermore, the rotational speed of the cylindrical portion 2k depends on the torque applied to the drive motor 500. From this, the torque to the motor changes depending on the amount of developer in the developer supply container 1 and the speed of the cylindrical portion 2k may also change. Therefore, the stop position of the pump portion 3a is made the same every time. Is difficult.

  Therefore, in order to stop the pump portion 3a at a predetermined position every time, it is necessary to provide a region in the cam groove 2e where the pump portion 3a does not reciprocate even when the cylindrical portion 2k is rotating. In this example, a cam groove 2i shown in FIG. 12 is provided to prevent the pump portion 3a from reciprocating. The cam groove 2i has a straight shape in which a groove is dug in the rotation direction of the cylindrical portion 2k, and the reciprocating member 3b does not move even if rotated. That is, the operation stop process is a state where the reciprocating member engaging projection 3c is engaged with the cam groove 2i.

  Further, the fact that the pump unit 3a does not reciprocate means that the developer is not discharged from the discharge port 4a (developer that drops from the discharge port 4a due to vibration during rotation of the cylindrical portion 2k or the like is allowed). That is, the cam groove 2i may be inclined in the rotation axis direction with respect to the rotation direction as long as the exhaust process and the intake process through the discharge port 4a are not performed. Further, since the cam groove 2i is inclined, a reciprocating operation corresponding to the inclination of the pump portion 3a is allowed.

(Changes in internal pressure of developer supply container)
Next, a verification experiment was conducted as to how the internal pressure of the developer supply container 1 changed. Hereinafter, this verification experiment will be described.

The developer replenishing container 1 is filled with the developer so that the developer accommodating space in the developer replenishing container 1 is filled with the developer, and the pump unit 3a is expanded and contracted by a volume change amount of 5 cm ³ . The change in internal pressure was measured. The internal pressure of the developer supply container 1 was measured by connecting a pressure gauge (manufactured by Keyence Corporation, model name: AP-C40) to the developer supply container 1.

  FIG. 13 shows the change in pressure when the pump unit 3a is expanded and contracted in a state where the shutter 4b of the developer supply container 1 filled with the developer is opened and the discharge port 4a can communicate with external air. Show.

  In FIG. 13, the horizontal axis indicates time, and the vertical axis indicates the relative pressure in the developer supply container 1 with respect to the atmospheric pressure (reference (1 kPa)) (+ indicates the positive pressure side, and − indicates the negative pressure side). ing).

  When the volume of the developer supply container 1 increases and the internal pressure of the developer supply container 1 becomes negative with respect to the external atmospheric pressure, air is taken in from the discharge port 4a due to the pressure difference. Further, when the volume of the developer supply container 1 decreases and the internal pressure of the developer supply container 1 becomes a positive pressure with respect to the atmospheric pressure, pressure is applied to the internal developer. At this time, the internal pressure is relieved by the amount of developer and air discharged.

  As a result of this verification experiment, it was confirmed that the internal pressure of the developer supply container 1 became negative with respect to the external atmospheric pressure by increasing the volume of the developer supply container 1, and that air was taken in due to the pressure difference. . In addition, as the volume of the developer supply container 1 decreases, the internal pressure of the developer supply container 1 becomes positive with respect to the atmospheric pressure, and the developer is discharged when pressure is applied to the internal developer. It could be confirmed. In this verification experiment, the absolute value of the pressure on the negative pressure side was about 1.2 kPa, and the absolute value of the pressure on the positive pressure side was about 0.5 kPa.

  Thus, in the case of the developer supply container 1 having the configuration of this example, the internal pressure of the developer supply container 1 is alternately switched between the negative pressure state and the positive pressure state in accordance with the intake operation and the exhaust operation by the pump unit 3a. It was confirmed that the developer can be discharged properly.

  As described above, in this example, the developer replenishment container 1 is provided with a simple pump unit that performs an intake operation and an exhaust operation. Can be performed stably.

  That is, with the configuration of this example, even when the size of the discharge port 4a is very small, the developer can be passed through the discharge port 4a in a fluidized state with a low bulk density. High discharge performance can be ensured without imposing large stress on the water.

  Further, in this example, since the inside of the variable volume type pump unit 3a is used as the developer storage space, a new developer storage space is obtained when the internal pressure is reduced by increasing the volume of the pump unit 3a. Can be formed. Therefore, even when the inside of the pump unit 3a is filled with the developer, the bulk density can be lowered by adding air to the developer with a simple configuration (fluidizing the developer). be able to). Therefore, the developer supply container 1 can be filled with the developer at a higher density than before.

(Modified cam groove setting conditions)
Next, a modified example of the setting condition of the cam groove 2e will be described with reference to FIG. The influence of the change in the shape of the cam groove 2e on the operating conditions of the pump unit 3a will be described with reference to a development view of the drive conversion mechanism unit shown in FIG.

  Here, in FIG. 12, the arrow A indicates the rotation direction of the cylindrical portion 2k (the movement direction of the cam groove 2e), the arrow B indicates the extension direction of the pump portion 3a, and the arrow C indicates the compression direction of the pump portion 3a. The cam groove 2e has a structure in which the groove used when compressing the pump portion 3a is the cam groove 2g, the groove used when extending the pump portion 3a is the cam groove 2h, and the pump portion 3a described above is used. The cam groove (pump part non-operating part) 2i does not reciprocate. Further, assuming that the angle formed by the cam groove 2g with respect to the rotation direction A of the cylindrical portion 2k is α and the angle formed by the cam groove 2h is β, the amplitude in the expansion / contraction directions B and C of the pump portion 3a of the cam groove (= expansion / contraction of the pump portion 3a) The length) is K1 as described above.

  First, the expansion / contraction length K1 of the pump part 3a will be described.

  For example, when the expansion / contraction length K1 is shortened, that is, the volume variable amount of the pump unit 3a is reduced, the pressure difference that can be generated with respect to the external air pressure is also reduced. Therefore, the pressure applied to the developer in the developer supply container 1 decreases, and as a result, the amount of the developer discharged from the developer supply container 1 per one cycle of the pump part (= the pump part 3a is expanded and contracted once). Decrease.

  Therefore, as shown in FIG. 14, if the cam groove amplitude K2 is set to K2 <K1 while the angles α and β are constant, the pump unit 3a is reciprocated once in the configuration shown in FIG. It is possible to reduce the amount of developer discharged into the printer. On the other hand, if K2> K1, the developer discharge amount can naturally be increased.

  Further, with respect to the angles α and β of the cam groove, for example, when the angle is increased, if the rotation speed of the cylindrical portion 2k is constant, the reciprocating member engaging protrusion that moves when the developer accommodating portion 2 rotates for a predetermined time. Since the moving distance of 3c increases, the extension / contraction speed of the pump part 3a increases as a result.

  On the other hand, since the resistance received from the cam groove 2g and the cam groove 2h when the reciprocating member engaging projection 3c moves in the cam groove 2g and the cam groove 2h is increased, the torque required to rotate the cylindrical portion 2k as a result. Will increase.

  Therefore, as shown in FIG. 15, the angle α ′ of the cam groove 2g and the angle β ′ of the cam groove 2h are set to α ′> α and β ′> β while the expansion / contraction length K1 is constant. For example, the expansion / contraction speed of the pump unit 3a can be increased with respect to the configuration of FIG. As a result, the number of expansions / contractions of the pump part 3a per rotation of the cylindrical part 2k can be increased. Furthermore, since the flow rate of the air entering the developer supply container 1 from the discharge port 4a is increased, the disentangling effect of the developer present around the discharge port 4a is improved.

  Conversely, if α ′ <α and β ′ <β are set, the rotational torque of the cylindrical portion 2k can be reduced. For example, when a developer with high fluidity is used, when the pump unit 3a is extended, the developer present around the discharge port 4a is easily blown away by the air that has entered from the discharge port 4a. As a result, the developer cannot be sufficiently stored in the discharge portion 4c, and the developer discharge amount may be reduced. In this case, if the extension speed of the pump unit 3a is reduced by this setting, the discharge capacity can be improved by suppressing the blowing of the developer.

  Further, if the angle α <angle β is set as in the cam groove 2e shown in FIG. 16, the extension speed of the pump portion 3a can be increased with respect to the compression speed. Conversely, if the angle α> the angle β is set, the extension speed of the pump unit 3a can be reduced with respect to the compression speed.

  Accordingly, for example, when the developer in the developer supply container 1 is in a high density state, the operating force of the pump unit 3a is larger when the pump unit 3a is compressed than when the pump unit 3a is expanded. When the portion 3a is compressed, the rotational torque of the cylindrical portion 2k tends to be higher. However, in this case, if the cam groove 2e is set to the configuration shown in FIG. 16, the developer releasing effect when the pump portion 3a is extended can be increased compared to the configuration shown in FIG. Furthermore, the resistance that the reciprocating member engaging projection 3c receives from the cam groove 2e when the pump portion 3a is compressed is reduced, and it is possible to suppress an increase in rotational torque when the pump portion 3a is compressed.

  In addition, as shown in FIG. 17, you may provide the cam groove 2e so that the reciprocating member engaging protrusion 3c may pass the cam groove 2g immediately after passing the cam groove 2h. In this case, an exhaust operation is started immediately after the pump unit 3a performs an intake operation. Since the process of stopping the operation in the extended state of the pump unit 3a in FIG. 12 is excluded, the decompressed state in the developer supply container 1 is not maintained during the operation stop being removed, and the effect of releasing the developer T is weakened. End up. However, since the process of stopping the operation is excluded, many intake / exhaust steps can be taken during one rotation of the cylindrical portion 2k, and a large amount of the developer T can be discharged.

  Further, as shown in FIG. 18, the operation stop process can be provided during the exhaust process and the intake process in addition to the state in which the pump unit 3a is contracted most or the state in which the pump unit 3a is expanded most. Thus, it is possible to set the required volume variable amount, and the pressure in the developer supply container 1 can be adjusted.

  As described above, the discharge capacity of the developer supply container 1 can be adjusted by changing the shape of the cam groove 2e in FIGS. It is possible to appropriately cope with the amount of the developer and the physical properties of the developer to be used.

  As described above, in this example, the driving force for rotating the cylindrical portion 2k provided with the conveying protrusion (spiral convex portion 2c) and the driving force for reciprocating the pump portion 3a are used as one drive receiving portion. The configuration is such that it is received by the (gear portion 2d). Therefore, the configuration of the drive input mechanism of the developer supply container can be simplified. Further, since the driving force is applied to the developer supply container by one drive mechanism (drive gear 300) provided in the developer supply device, it can contribute to simplification of the drive mechanism of the developer supply device. it can.

  Further, according to the configuration of this example, the rotational drive force for rotating the cylindrical portion 2k received from the developer supply device is driven and converted by the drive conversion mechanism of the developer supply container. 3a can be appropriately reciprocated.

(Regulation Department)
Next, the restricting portion 7 which is the most characteristic configuration of the present invention will be specifically described with reference to FIGS. 7 and 19 to 23. FIG. 7A is a cross-sectional perspective view of the developer supply container, FIG. 7B is a partial cross-sectional view when the pump is fully expanded, and FIG. FIG. FIG. 19A is a perspective view of the entire conveying member 6 installed in the container of Example 1, FIG. 19B is a side view of the conveying member 6, and FIGS. It is sectional drawing which looked at the mode in a container from the pump part 3a side of FIG.

  As shown in FIG. 7A, in this configuration, the restricting portion 7 is integrally provided at the end of the conveying member 6 on the pump portion 3a side. For this reason, the restricting portion 7 is also rotated in conjunction with the rotation operation of the conveying member 6 that rotates integrally with the cylindrical portion 2k.

  And as shown in FIG. 19, the control part 7 has two thrust suppression walls 7a and 7b provided in parallel at positions separated by a width S in the rotation axis direction (arrow X in FIG. 7 (b)), It is comprised by the two radial suppression walls 7c and 7d provided in the rotation direction. Further, a container opening 7e is formed in the vicinity of the center of the rotation axis of the thrust suppression wall 7a on the pump unit 3a side so that the space in the developer container 2 and the space in the regulating part 7 can communicate with each other. In the present embodiment, the accommodating portion opening 7e is provided on the side surface of the restricting portion 7 on the pump portion side. In addition, a communication passage opening that can communicate with the communication passage 4d at a location surrounded by outer end portions of the two thrust restraining walls 7a and 7b and the two radial restraining walls 7c and 7d away from the center of the rotation axis. 7f is formed. That is, the position of the communication passage opening 7f in the rotation axis thrust direction is arranged at a position where at least a portion thereof overlaps the communication passage 4d. An air passage 7g in which the accommodation portion opening 7e and the communication passage opening 7f can communicate with each other inside the restriction portion 7 surrounded by the two thrust inhibition walls 7a and 7b and the two radial inhibition walls 7c and 7d. Is formed. In the present embodiment, the restricting portion 7 covers the communication path 4d in the direction of the rotation axis.

  Next, the operation of the restriction unit 7 during the developer supply process will be described with reference to FIGS. FIG. 20 is a cross-sectional view of the discharge unit during the operation stop process of the pump unit in the first embodiment. FIG. 21 is a cross-sectional view of the discharge portion during intake in the first embodiment. FIG. 22 is a cross-sectional view of the discharge portion during exhaust according to the first embodiment. FIG. 23 is a cross-sectional view of the discharge portion after the developer is discharged in the first embodiment.

  In FIG. 20, the developer supply container 1 is in an operation stop process in which the pump portion 3a is stopped as the cylindrical portion 2k rotates.

  At this time, the restricting portion 7 rotates with the rotation of the conveying member 6, and the communication passage opening 7f of the restricting portion 7 does not cover the upper portion of the communicating passage 4d located at the bottom of the discharge portion 4c. . Further, since the pump unit 3a is an operation stop process, the internal pressure in the developer containing unit 2 does not change without reciprocating. Here, in this embodiment, the conveying member 6 has a function of a moving part that moves the restricting part 7 so as to move to the upper part (inlet area) of the opening of the communication path 4d and to retreat from the inlet area.

  As a result, the regulating portion 7 does not act on the communication path 4d, and the developer T conveyed to the vicinity of the upper part of the communication path 4d by the conveying member 6 flows into the communication path 4d and is stored. (Developer inflow unregulated state).

  The conveyance member 6 rotates from this developer inflow non-regulated state, resulting in the state shown in FIG.

  In FIG. 21, the pump unit 3 a is in a state of being on the way from the most contracted state to the most extended state, that is, an intake process.

  At this time, the restricting portion 7 rotates with the rotation of the conveying member 6, and a part of the upper portion of the communication passage 4 d from the state where the communication passage opening 7 f of the restriction portion 7 does not cover the upper portion of the communication passage 4 d. It will be in a state of covering. Further, since the pump unit 3a is an intake process, the pump unit 3a extends, so that the pressure in the developer storage unit 2 is reduced, and the air outside the developer supply container 1 becomes the pressure inside and outside the developer supply container 1. Due to the difference, it moves into the developer supply container 1 through the discharge port 4a.

  As a result, the developer T stored in the communication path 4d in the above-described process includes air taken in from the discharge port 4a, so that the bulk density is reduced and the developer T is fluidized.

  Further, the state of the upper part of the communication path 4d is that, as the restriction part 7 rotates, the communication path opening 7f of the restriction part 7 covers the upper part of the communication path 4d, so that the radial inhibition wall 7c on the downstream side in the rotation direction of the restriction part 7 Then, the developer T in the upper part of the communication path 4d is pushed away. Further, the upper part of the communication path 4d is partially covered by the communication path opening 7f of the restricting portion 7. As a result, the state where the inflow of the developer T in the vicinity of the upper portion of the communication passage 4d into the communication passage 4d is restricted by the thrust inhibition walls 7a and 7b and the radial inhibition walls 7c and 7d of the restriction portion 7 (developer inflow restriction state). )

  The conveyance member 6 is further rotated from the developer inflow regulation state, and the state shown in FIG. 22 is obtained.

  In FIG. 22, the pump unit 3 a is in the middle of moving from the most extended state to the most contracted state, that is, an exhaust process.

  At this time, the restricting portion 7 rotates with the rotation of the conveying member 6, and at least a part of the communication passage opening 7f of the restricting portion 7 always covers the upper portion of the communication passage 4d. ing. Further, since the pump unit 3a is an exhaust process, the internal pressure in the developer supply container 1 becomes higher than the atmospheric pressure when the pump unit 3a contracts, so that the air in the developer supply container 1 becomes the developer supply container. Due to the pressure difference between the inside and the outside, the developer 1 moves out of the developer supply container 1 through the discharge port 4a.

  As a result, the developer T fluidized in the communication path 4d in the above-described intake process is discharged to the developer supply device 201 through the discharge port 4a.

  Also in this exhaust process, the state of the upper part of the communication path 4d is the same as the above-described intake process, and the radial restraint wall 7c on the downstream side in the rotation direction of the restricting part 7 is connected to the upper part of the communicating path 4d. The toner is pushed away. Furthermore, with respect to the upper part of the communication path 4d, a part of the communication path opening 7f of the restricting portion 7 always covers the upper part of the communication path 4d. As a result, in the exhaust process, the flow of the developer T in the vicinity of the upper part of the communication path 4d into the communication path 4d is always regulated by the thrust suppression walls 7a and 7b and the radial suppression walls 7c and 7d of the regulation unit 7. State (developer inflow regulation state).

  Here, the air flow in the developer supply container 1 that acts on the developer T in the communication path 4d during the exhaust process will be specifically described. In this configuration, the air flow to the communication passage 4d during the exhaust process includes the following two types.

  One is a regulating portion 7 that communicates from the inside of the pump portion or developer accommodating portion 2 with the accommodating portion opening 7e provided in the vicinity of the center of the rotation axis of the regulating portion 7, the air passage 7g inside the regulating portion 7, and the communication passage 4d. The air flow moves in the order of the communication passage openings 7f and acts on the developer T in the communication passage 4d. The other is the flow of air that acts on the developer T in the communication path 4d through the gap between the upper part of the communication path 4d and the restriction portion 7 that covers the upper part of the communication path 4d.

  However, for the following reasons, the air flow to the communication passage 4d during the exhaust process is mainly the former air flow.

  During the exhaust process, the developer T in the vicinity of the outer periphery of the communication passage opening 7f of the restriction portion 7 covering the upper portion of the communication passage 4d is placed in the communication passage 4d by the thrust prevention walls 7a and 7b and the radial inhibition walls 7c and 7d of the restriction portion 7. Inflow into the city is regulated. Therefore, since the developer T stays in the vicinity of the outer periphery of the communication passage opening 7f of the restricting portion 7, the staying developer T becomes resistant to the air flow to the communication passage 4d. On the other hand, the vicinity of the housing opening 7e provided in the vicinity of the rotation axis of the restricting portion 7 is positioned higher in the vertical direction than the communication passage opening 7f during the exhaust process. However, the retention of the developer T is small and the resistance to the air flow is small. As a result, the main air flow during the exhaust process is mainly the air flow passing through the air passage 7g in the former restricting portion 7, which is less resistant to the air flow by the developer T. is there.

  As a result, during the exhausting process, the developer T in the communication path 4d that can communicate with the air passage 7g by the air that has passed through the air passage 7g inside the regulating portion 7 is transferred to the developer supply device 201 together with the air flow. Will be discharged. Further, as described above, during the exhaust process, the communication passage 4d is in a developer inflow restriction state in which the flow of the developer T is always restricted by the restriction portion 7, and therefore a substantially constant amount of developer is placed in the communication passage 4d. Is stored.

  Further, the internal pressure in the developer supply container 1 during the exhaust process is such that the space inside and outside the developer supply container 1 communicates with the air flow when the developer T in the communication path 4d is discharged (FIG. 23). Thereafter, only air is released, and finally the pressure is equal to the pressure outside the developer supply container 1. That is, after the developer T in the communication path 4d is discharged, only air is released due to the pressure difference between the inside and outside of the developer supply container 1, and the developer T is not discharged. Therefore, during the exhaust process, only a fixed amount of developer T stored in the communication path 4d is discharged, so that the developer T can be discharged to the developer supply device 201 with very high supply accuracy.

  In the exhaust process, it is desirable that the communication passage opening 7f of the restricting portion 7 completely covers the upper portion of the communication passage 4d without any gap. As a result, the developer T near the upper portion of the communication passage 4d does not flow into the communication passage 4d during the exhaust process, and more stable replenishment accuracy can be obtained.

  Here, as a comparative example, a configuration without the restricting portion 7 will be described with reference to FIG. FIG. 24 is the same as the present configuration except that the restriction unit 7 is excluded as compared with the present configuration.

  As shown in FIG. 24, in the configuration of the comparative example, there is no restriction portion 7 above the communication path 4d, and the developer T is always open, and the developer T flowing into the communication path 4d flows into the communication path 4d. There is no control such as regulation. Therefore, the developer T discharged to the developer replenishing device 201 in the exhaust process is an uncontrollable amount of developer in the vicinity of the upper portion of the communication path 4d in addition to the developer T stored in a certain amount in the communication path 4d. T is also discharged together. The uncontrollable amount of developer in the configuration of this comparative example is the developer T affected by the uncontrolled developer powder surface in the developer supply container 1 mainly in the vicinity of the upper portion of the communication path 4d. pointing. When the developer powder level is not controlled, the developer powder level near the upper part of the communication path 4d may be high or low, and the amount of developer flowing into the communication path 4d during the exhaust process is uncontrollable and not constant. . Therefore, in the comparative example, an uncontrollable amount of developer T in the vicinity of the upper portion of the communication path 4d is discharged during the exhaust process.

  In the comparative example, since the upper part of the communication path 4d is open during the exhaust process, the developer T always exists in the upper part of the discharge port 4a, and the pressure difference between the inside and outside of the developer supply container 1 causes Until the internal pressure becomes equal to the atmospheric pressure, the developer T continues to be discharged along with the air flow.

  Therefore, in the comparative example, the uncontrollable developer amount in the vicinity of the upper part of the communication path 4d continues to be discharged during the exhaust process, so that it is very difficult to obtain the replenishment accuracy required in the configuration of the present embodiment. is there.

  On the other hand, in the configuration of the present embodiment described above, the developer T near the upper portion of the communication path 4d is pushed away by the radial deterrent wall 7c on the downstream side in the rotation direction of the restricting portion 7 to develop the developer T. The developer powder surface in the communication path 4d is controlled to be constant by making the powder powder surface constant. Further, the restriction portion 7 covers the communication path 4d, thereby restricting the inflow of the developer T into the communication path 4d and keeping the developer powder surface in the communication path 4d constant. In the exhaust process, when the developer T in the communication path 4d is discharged as described above, the space inside and outside the developer supply container 1 communicates, and then only air is released, so that the developer supply It is possible to prevent the developer T from being continuously discharged due to the pressure difference between the inside and outside of the container 1.

  From the above, the present configuration provided with the regulating portion 7 can discharge a constant amount of developer T stored in the communication path 4d to the developer supply device 201 at all times in the exhaust process, and is very stable. It can be said that the developer T can be discharged with the replenishment accuracy.

  FIG. 23 shows a state after the developer in the communication path 4d is discharged. At this time, there is no developer T in the communication path 4d except for the amount attached to the wall surface. When the conveying member 6 further rotates from here, the state returns to the state of FIG. 20 and the same process is repeated. Therefore, by using this configuration, it is possible to always discharge the developer T with a stable replenishment accuracy from the early stage to the late stage of the discharge, and the regulation unit 7 is very effective for dealing with high replenishment accuracy. It can be said that it is a proper configuration.

  In addition, in this structure, although the control part 7 becomes the structure attached to two places with respect to the conveyance member 6, the structure of this invention is not restricted to this. As described above, since this configuration has a cam configuration including two exhaust steps while the cylindrical portion 2k rotates 360 °, the two restriction portions 7 are provided. For example, when the cylindrical part 2k rotates 360 °, if the exhaust process is performed three times, the arrangement may be such that three restricting parts 7 are provided.

  In the present configuration, as described above, the restricting portion 7 is provided integrally with the conveying member 6 that is a moving portion, and the restricting portion 7 is also interlocked with the operation in which the conveying member 6 rotates integrally with the cylindrical portion 2k. Is configured to rotate. In this configuration, the driving force for rotating the cylindrical portion 2k and the driving force for reciprocating the pump portion 3a are received by one drive receiving portion (gear portion 2d) as described above. Further, the driving force for rotating the restricting portion 7 is also received by one drive receiving portion (gear portion 2d) together with the driving force for rotating the cylindrical portion 2k. In other words, this configuration requires three driving forces, namely, the rotation of the cylindrical portion 2k, the reciprocation of the pump portion 3a, and the rotation of the regulating portion 7, and these three driving forces are used as one drive receiving portion (gear portion 2d). ).

  Therefore, this configuration can greatly simplify the configuration of the drive input mechanism of the developer supply container 1 as compared to the case where three drive receiving portions are separately provided in the developer supply container 1. Furthermore, since it is configured to receive driving from one drive mechanism (drive gear 300) of the developer supply device 201, it can greatly contribute to simplification of the drive mechanism of the developer supply device 201.

  In addition, since the two driving operations relating to the discharge of the developer T, that is, the reciprocating motion of the pump unit 3a and the rotation of the regulating unit 7, are interlocked with the rotation of the cylindrical unit 2k, the configuration of the pump unit 3a and the regulating unit are as follows. Adjustment of the timing for driving 7 is very easy.

<Modification 1>
The developer supply container 1 of the present invention is not limited to the developer supply container 1 described in the first embodiment. For example, as a modification, the same performance can be obtained in the developer supply container 1 as shown in FIGS.

  FIGS. 25A and 25B are cross-sectional perspective views of the developer supply container 1. 25A shows a state where a contact portion 6b and a contact portion 7i described later are separated from each other, and FIG. 25B shows a state where the contact portion 6b and the contact portion 7i are in contact with each other. Moreover, in this modification, only the structure of the conveyance member 6 and the control part 7 differs from Example 1, and the other structure is substantially the same as Example 1. FIG. Therefore, in the present modification, the same reference numerals are assigned to the same configurations as those in the first embodiment described above, and detailed description thereof is omitted.

  In this modification, as shown in FIG. 25, instead of the configuration in which the conveying member 6 and the regulating portion 7 are provided integrally as in the first embodiment, the conveying member 6 and the regulating portion 7 are provided separately. It has a configuration. As with the first embodiment, the conveying member 6 is configured to rotate integrally with the cylindrical portion 2k that is rotationally driven by the rotational driving force received from the developer supply device 201. As shown in FIG. 25, the restricting portion 7 is held in a state where the rotation center shaft portion 7h of the restricting portion 7 is rotatably supported by a shaft holding portion 4e provided in the discharge portion 4c.

  Further, as shown in FIG. 25, the conveying member 6 and the restricting portion 7 in the present modification are provided with a contact portion 6b and a contact portion 7i, respectively. The contact portion 6b and the contact portion 7i are arranged at positions where they can be contacted when the transport member 6 is rotated, and the contact portion 6b comes into contact with the contact portion 7i by the rotation of the transport member 6, so that the regulating portion 7 is It is configured to drive in conjunction with rotation. That is, also in the present modified example, similarly to the configuration of the first embodiment, the restricting portion 7 is also rotated in conjunction with the operation in which the conveying member 6 rotates integrally with the cylindrical portion 2k.

  Therefore, also in the present modification, the regulation unit 7 at the developer replenishment process is driven in the same manner as in the first embodiment described above, so that the operation stop process, the intake process, and the exhaust process illustrated in FIGS. At the same time, the same effect as in the first embodiment can be obtained. Therefore, in the present modified example in which the restricting portion 7 is provided, a constant amount of the developer T stored in the communication path 4d can always be discharged to the developer replenishing device 201 in the exhausting process, and a very stable replenishment is possible. It can be said that the developer T can be discharged with accuracy. Further, in this modified example, since the restricting portion 7 is held on the discharge portion 4c side, a clearance between the outer end portion of the restricting portion 7 away from the rotation axis center and the inner wall of the discharge portion 4c is implemented. It becomes possible to control more accurately than in Example 1, and more stable replenishment accuracy can be obtained.

  Further, this modification also requires three driving forces, that is, rotation of the cylindrical portion 2k, reciprocation of the pump portion 3a, rotation of the restricting portion 7, and these three driving forces are converted into one drive receiving portion (gear portion). 2d).

  Therefore, also in this modification, the configuration of the drive input mechanism of the developer supply container 1 can be greatly simplified as compared to the case where three drive receiving portions are separately provided in the developer supply container 1. Become. Furthermore, since it is configured to receive driving from one drive mechanism (drive gear 300) of the developer supply device 201, it can greatly contribute to simplification of the drive mechanism of the developer supply device 201.

[Example 2]
Next, Example 2 will be described with reference to FIGS. 26, 27, and 28. FIG. FIG. 26 is a partial cross-sectional perspective view of the developer supply container 1 according to the second embodiment. FIG. 27A is a perspective view of the conveying member 6 according to the second embodiment, and FIG. 27B is a partial cross-sectional perspective view of the conveying member 6. 28 (a) and 28 (b) are cross-sectional views of the inside of the container during the replenishment operation as seen from the pump part 3a side in FIG.

  As shown in FIGS. 26 and 27, the present embodiment has a configuration in which the shape of the restricting portion 7 provided integrally with the conveying member 6 is changed as compared with the first embodiment. Other configurations are the same as those in the first embodiment. For this reason, the description which overlaps with Example 1 is abbreviate | omitted, and demonstrates the structure used as the characteristic of a present Example here. Further, members having the same functions as those of the above-described embodiments are denoted by the same reference numerals.

  In the present embodiment, the difference from the configuration of the first embodiment is that the position of the accommodating portion opening 7e of the restricting portion 7 in a state where the inflow of the developer T into the communication path 4d is restricted (developer inflow restricted state). It is. Details will be described below.

  In the first embodiment, as shown in FIG. 22, the position of the accommodating portion opening 7e in the developer inflow restricted state is provided in the vicinity of the rotation axis center of the thrust inhibiting wall 7a on the pump portion 3a side. On the other hand, in the present embodiment, as shown in FIG. 28, the position of the accommodating portion opening 7e in the developer inflow restricting state is provided in the vicinity of the uppermost end in the vertical direction of the discharging portion 4c.

  As shown in FIG. 28, in the developer inflow restricted state, the communication passage opening 7f provided in the restricting portion 7 is provided in the vicinity of the lowermost end in the vertical direction of the discharge portion 4c, as in the first embodiment. Further, the air passage 7g provided inside the restricting portion 7 is also provided as a space connecting the accommodating portion opening 7e and the communication passage opening 7f, as in the first embodiment. Therefore, in this embodiment, in the developer inflow regulation state, the air passage 7g inside the regulation part 7 is a space that connects the vicinity of the uppermost end in the vertical direction and the vicinity of the lowermost end of the discharge part 4c. Further, in this embodiment, as shown in FIG. 27, one opening has a configuration in which the phase is reversed by the rotation of the restricting portion 7 and serves as both the accommodating portion opening 7e and the communication passage opening 7f.

  In the developer replenishing step shown in FIG. 28, also in this embodiment, as in the first embodiment, the same effect as that in the first embodiment can be obtained by rotationally driving the regulating portion 7. Therefore, as described above, the present embodiment provided with the restricting portion 7 can always discharge a constant amount of developer T stored in the communication path 4d to the developer supply device 201 in the exhaust process, It can be said that the developer T can be discharged with very stable replenishment accuracy.

  Furthermore, in the present embodiment, the position of the accommodating portion opening 7e is provided in the vicinity of the uppermost end in the vertical direction of the discharge portion 4c in the developer inflow regulation state. The developer T can be discharged with accuracy. Details are described below.

  As in the first embodiment shown in FIG. 22, when the accommodating portion opening 7e is located near the center of the rotation axis of the restricting portion 7, the developer powder surface in the developer supply container 1 is located near the accommodating portion opening 7e. If it is positioned, the developer T may flow into the restricting portion 7 from the accommodating portion opening 7e. When the developer T flows from the housing opening 7e in the developer inflow regulation state, the developer T passes through the ventilation path 7g and the communication path opening 7f and enters the communication path 4d covered by the regulation section 7. There is a possibility that it will additionally flow in. Therefore, at the time of the exhaust process, as described above, in the present configuration including the restricting portion 7, only the developer T in the communication passage 4d is discharged, but additionally flows into the communication passage 4d from the accommodating portion opening 7e. An uncontrollable amount of developer T may also be discharged together. As a result, in Example 1, the developer can be discharged with a very stable replenishment accuracy, but it is affected by the flow of an uncontrollable amount of developer T from the developer powder surface into the communication path 4d. There was a possibility of fluctuations in emissions.

  However, in this embodiment, as shown in FIG. 28, in the developer inflow restricted state, the container opening 7e is located in the vicinity of the uppermost end in the vertical direction of the discharge part 4c. The possibility of being located in the vicinity of the opening 7e is very small compared to the first embodiment. Therefore, the probability that the developer T flows into the restricting portion 7 from the accommodating portion opening 7e can be greatly reduced, which is more advantageous than the first embodiment in terms of preventing the developer T from flowing into the restricting portion 7. It can be said that it is a proper configuration. Therefore, in the developer inflow regulation state, there is almost no amount of the developer T additionally flowing into the communication path 4d covered with the restriction portion 7, and the amount of the developer T in the communication path 4d is always in a stable state. Become. As a result, at the time of the exhaust process, the present configuration including the restricting portion 7 discharges only the developer T in the communication path 4d as described above, so that the developer T is more reliably discharged with stable replenishment accuracy. This is possible and can be said to be a more preferable configuration than the first embodiment.

DESCRIPTION OF SYMBOLS S ... Sheet T ... Developer 1 ... Developer supply container 2 ... Developer accommodating part 2c ... Conveyance protrusion 2d ... Gear part 2e, 2g, 2h, 2i ... Cam groove 2k ... Cylindrical part 3a ... Pump part 3b ... Reciprocating member 3c: Reciprocating member engagement protrusion 3f: Protection member rotation restricting portion 4 ... Flange portion 4a ... Discharge port 4b ... Shutter 4c ... Discharge portion 4d ... Communication path 4e ... Shaft holding portion 5b ... Flange seal 6 ... Conveying member 6a ... Inclination Rib 6b ... contact part 7 ... restricting part 7a, 7b ... thrust restraint wall 7c, 7d ... radial restraint wall 7e ... accommodating part opening 7f ... communication passage opening 7g ... vent passage 7h ... rotation center shaft part 7i ... contact part 10 ... mounting Part 10a: Hopper 10b ... Conveying screw 10c ... Opening 10d ... Developer sensor 11 ... Rotation restricting part 13 ... Developer receiving port 21 ... Abutting part 100 ... Device Body 104 ... photoreceptor 201 ... developer supplying apparatus 201a ... developing device 300 ... driving gear 500 ... driving motor 600 ... control device

Claims (16)

In the developer accommodating container detachably mountable to a developer supply device,
A developer accommodating portion for accommodating the developer, a discharge port for discharging the developer accommodated in the developer accommodating portion, and the inside of the developer accommodating container and the discharge port can be communicated with each other via the discharge port. A storage section for storing the developer to be discharged, a pump section for sending air to at least the storage section for discharging the developer from the storage section, and a rotatable rotating member provided facing the storage section; , has a,
The rotating member is provided so as to separate a part of the space when viewed from the direction of the rotation axis of the rotating member, and has a first partition wall portion that has an internal space and rotates about the rotation axis; A first opening provided in a peripheral surface of the first partition wall so as to be able to communicate with an internal space of the one partition wall, and a side wall on the pump part side of the first partition wall, A first side opening that communicates with the internal space of the partition wall, and a first side opening that is provided to separate a part of the space when viewed from the direction of the rotation axis, has an internal space, and rotates about the rotation axis. A second opening provided in the peripheral surface of the second partition wall so as to be able to communicate with the internal space of the second partition wall, and a side wall on the pump part side of the second partition wall A second side surface opening provided in communication with the internal space of the second partition wall, and the rotating member A transport unit that transports the developer to a space between the first partition wall and the second partition wall in the rotation direction, the first partition wall and the second partition wall facing the storage unit. developer container, characterized in that it is arranged at a position. 2. The pump unit according to claim 1, wherein the pump unit is extendable, and the pump unit operates so that the pump unit compresses at least when the first opening faces the storage unit. Developer container. 3. The developer container according to claim 1, wherein the first partition wall portion, the second partition wall portion, and the transport portion rotate integrally. The first partition wall and the second partition wall are arranged so that at least a part of the first partition wall and a part of the second partition wall overlap the storage part in the direction of the rotation axis. The developer container according to any one of claims 1 to 3, wherein the developer container is provided. The said 1st partition part and said 2nd partition part are arrange | positioned between the said developer accommodating part and the said pump part in the direction of the said rotation axis. A developer container according to any one of the above. 6. The developer according to claim 1, further comprising a storage portion having the storage portion and the rotation member, wherein the rotation member is disposed in a cylindrical portion in the storage portion. Containment container. The developer container according to claim 1, wherein the container is rotatable relative to the developer container. The developer container according to any one of claims 1 to 7, wherein the first partition wall and the second partition wall are disposed at positions facing the rotation center. In the developer accommodating container detachably mountable to a developer supply device,
The developer accommodating portion for accommodating the developer, the discharge port for discharging the developer accommodated in the developer accommodating portion, and the inside of the developer accommodating container and the discharge port can communicate with each other, and the discharge is performed through the discharge port. A storage section for storing the developer to be discharged, a pump section for sending air to at least the storage section in order to discharge the developer from the storage section, and a rotatable rotating member provided to face the storage section. And
The rotating member is provided so as to separate a part of the space when viewed from the direction of the rotation axis of the rotating member, has an internal space, and rotates around the rotation axis of the rotating member. An opening provided on a peripheral surface of the partition wall so as to be able to communicate with an internal space; a side opening provided on a side surface of the partition wall on the pump part side; and communicating with the internal space; and the storage anda conveying portion that conveys the developer in part, the developer accommodating container, wherein the partition wall is characterized in that it is arranged at a position opposed to the reservoir. The developing device according to claim 9, wherein the pump unit is extendable, and the pump unit operates so that the pump unit is compressed when at least the opening portion faces the storage unit. Agent container. The developer container according to claim 9 or 10, wherein the partition wall and the transport unit rotate together. 12. The development according to claim 9, wherein the partition wall portion is arranged so that at least a part of the partition wall portion overlaps the storage portion in the direction of the rotation axis. Agent container. The developer container according to any one of claims 9 to 12, wherein the partition wall is disposed between the developer container and the pump in the direction of the rotation axis. . 14. The developer according to claim 9, further comprising a storage portion having the storage portion and the rotation member, wherein the rotation member is disposed in a cylindrical portion in the storage portion. Containment container. The developer container according to claim 9, wherein the container is rotatable relative to the developer container. The developer storage container according to claim 9, wherein the partition wall is disposed at a position facing the rotation center.

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