JP2019082642A - Development system - Google Patents

Abstract

To suppress a developer from being discharged in excess from a development device.SOLUTION: A development system of the present invention collects a developer discharged from a development device 100 in a developer collecting device 200 while the development device 100 is connected to the developer collecting device 200. The development device 100 comprises a housing 150 and a shutter 170 that performs opening/closing operation. The developer collecting device 200 includes a drive mechanism 220 for opening/closing the shutter 170. A developer outlet H for discharging a developer to the developer collecting device 200 is provided in an insertion part 155 of the housing 150. The drive mechanism 220 opens/closes the shutter 170 while the development device 100 is connected to the developer collecting device 200 and thereby adjusts the aperture area of the developer outlet H.SELECTED DRAWING: Figure 7

Description

  The present invention relates to a developing system which recovers a developer discharged from a developing device in a state where the developing device is connected to the developer recovery device.

  In the art of electrophotography, there is a developing device using a two-component developer. In such a developing device, a new developer is supplied into the developer storage chamber in order to prolong the life of the developer. Then, the developing device discharges the aged developer from the developer discharge port. The discharged developer is collected by a developer collection device. Such a developing device is described, for example, in Patent Document 1.

JP, 2008-26365, A

  In a developing device provided with a developer discharge port, the developer scattered in the developer storage chamber rides on the air flow and is unintentionally discharged from the developer discharge port due to an increase in internal pressure during operation of the developing device. There is a thing. For this reason, in the present technical field, there is a demand for suppressing excessive discharge of the developer from the developing device.

  Therefore, an object of the present invention is to provide a developing system capable of suppressing excessive discharge of the developer from the developing device.

  The developing system of the present invention includes a developing device and a developer recovery device, and with the developing device connected to the developer recovery device, the developer discharged from the developing device is recovered to the developer recovery device. The developing device includes a case for containing a developer and a shutter for performing an opening and closing operation. The developing device or the developer recovery device includes a drive mechanism that opens and closes the shutter. The case is provided with a developer discharge port for discharging the developer in the case to a developer recovery device. The shutter can adjust the opening area of the developer discharge port by performing an opening and closing operation. The drive mechanism adjusts the opening area of the developer discharge port by opening and closing the shutter in a state where the developing device is connected to the developer recovery device.

  This developing system can open and close the shutter even when the developing device is connected to the developer recovery device. That is, the opening area of the developer discharge port can be adjusted according to the operating state of the developing device, and the opening area of the developer discharge port can be adjusted according to various conditions. As described above, the development system can suppress excessive discharge of the developer from the developing device on the air flow by adjusting the opening area of the developer discharge port.

  In this developing system, the case is provided with a first storage section for storing the developer discharged from the developer discharge port at a position upstream of the developer discharge port in the discharge direction. The developer discharge port may discharge the developer in the first reservoir to the developer recovery device. In this case, the developer can be temporarily stored in the first storage portion before being discharged from the developer discharge port. Thus, even when the developer discharge port is closed by the shutter (small opening area), the developer can be prevented from being clogged in the case.

  The developing system of the present invention includes a developing device and a developer recovery device, and with the developing device connected to the developer recovery device, the developer discharged from the developing device is recovered to the developer recovery device. The developer recovery device includes a second storage unit for storing the developer discharged from the developing device connected to the developer recovery device, a shutter for opening and closing operations, and a drive mechanism for opening and closing the shutters. The second storage portion is provided with a developer discharge port for discharging the developer in the second storage portion into the collection space of the developer collection device. The shutter can adjust the opening area of the developer discharge port by performing an opening and closing operation. The drive mechanism adjusts the opening area of the developer discharge port by opening and closing the shutter in a state where the developing device is connected to the developer recovery device.

  This developing system can open and close the shutter even when the developing device is connected to the developer recovery device. That is, the opening area of the developer discharge port can be adjusted according to the operating state of the developing device, and the opening area of the developer discharge port can be adjusted according to the situation. As described above, the development system can suppress excessive discharge of the developer from the developing device on the air flow by adjusting the opening area of the developer discharge port. In addition, the developer can be temporarily stored in the second storage unit before being discharged from the developer discharge port. Thus, even when the developer discharge port is closed by the shutter (small opening area), the developer can be prevented from being clogged in the case.

  In this development system, the drive mechanism may be capable of switching the open / close state of the shutter between the developer non-discharge mode and the developer discharge mode. The developer non-discharge mode is a mode in which the opening area of the developer discharge port is set as the first opening area in a state where the developing device is connected to the developer recovery device. The developer discharge mode is a mode in which the opening area of the developer discharge port is set to a second opening area larger than the first opening area in a state where the developing device is connected to the developer recovery device. In this case, even when the developing device is connected to the developer recovery device, the developing system can switch the open / close state of the shutter to two modes, so the developer is excessively discharged from the developing device. Can be suppressed.

  In this developing system, the developing device includes a transport member for circulating the developer in the developing device. When the rotational speed of the conveyance member in the developer discharge mode is V1 and the rotation speed of the conveyance member in the developer non-discharge mode is V2, V1 ≦ V2 may be satisfied. When the rotation speed of the conveying member is high, a large amount of air is taken into the developing device, whereby the internal pressure of the developing device is increased, and the developer is easily discharged excessively from the developer discharge port due to the flow of air. For this reason, when the rotation speed of the conveyance member is fast, the developer can be prevented from being excessively discharged from the developing device by reducing the opening area.

  In this developing system, the drive mechanism may open and close the shutter by the weight of the developer accumulated on the shutter. In this case, a drive source for driving the shutter is not necessary, and the development system can be simplified.

  The development system includes a storage amount detection sensor that detects the storage amount of the developer in the first storage unit. The drive mechanism may open and close the shutter based on the detection result of the storage amount detection sensor. Further, a storage amount detection sensor for detecting the storage amount of the developer in the second storage portion is provided. The drive mechanism may open and close the shutter based on the detection result of the storage amount detection sensor. In this case, in the development system, the developer can be discharged according to the storage amount, and clogging of the developer can be suppressed.

  In this developing system, the drive mechanism has a shutter such that the opening area of the developer discharge port becomes larger than the opening area of the developer discharge port immediately before the driving of the developing device is stopped when the driving of the developing device is stopped. May be operated. When the developing device stops driving, the internal pressure of the developing device becomes lower than that during driving. For this reason, excessive discharge of the developer on the air flow is less likely to occur. Therefore, the developing system can discharge the old developer while suppressing excessive discharge of the developer by enlarging the opening area of the developer discharge port when the driving of the developing device is stopped.

  In this developing system, when the developing device starts driving, the drive mechanism has a shutter such that the opening area of the developer discharge port becomes smaller than the opening area of the developer discharge port when the driving of the developing device is stopped. May be operated. When the developing device starts driving, the internal pressure of the developing device becomes higher than when driving is stopped. For this reason, it becomes easy for the developer to be discharged excessively due to the flow of air. Therefore, the developing system can suppress the excessive discharge of the developer by reducing the opening area of the developer discharge port when the developing device starts driving.

  In this development system, the surface on the upstream side in the developer discharge direction in the shutter may be formed in a tapered shape, a bowl shape, or a flat plate shape. In this case, the developing system can appropriately discharge the developer, for example, the developer remaining on the shutter can be reduced when the shutter is opened.

  In this development system, the case is provided with a pressure release hole for adjusting the pressure in the case. The pressure relief hole may be covered by a filter. In this case, an increase in the internal pressure of the case of the developing device can be suppressed, and excessive discharge of the developer from the developing device can be suppressed.

  In this developing system, a plurality of developing devices are connected to the developer recovery device. The shutter and the drive mechanism are provided for each of the plurality of developing devices. Each of the plurality of drive mechanisms may open and close the respective shutters simultaneously or individually. As described above, even when a plurality of developing devices are connected to the developer recovery device, the developing system can properly open and close the shutter.

  According to the present invention, excessive discharge of the developer from the developing device can be suppressed.

FIG. 1 is a view showing a schematic configuration of an image forming apparatus according to an embodiment. FIG. 2 is a cross-sectional view showing a schematic configuration of a developing device. FIG. 6 is a perspective view showing the developing device connected to the developer recovery device. FIG. 5 is a schematic view showing the connection between a developing device and a developer recovery device. FIG. 6 is a schematic cross-sectional view showing the periphery of a connection between a developing device and a developer collection device. FIG. 5 is a schematic view showing the connection between a developing device and a developer recovery device. FIG. 6 is a schematic cross-sectional view showing the periphery of a connection between a developing device and a developer collection device. It is a schematic sectional drawing which shows the surroundings of the connection part of the image development apparatus and developer collection | recovery apparatus in a modification. It is a schematic sectional drawing which shows the surroundings of the connection part of the image development apparatus and developer collection | recovery apparatus in a modification. It is a schematic sectional drawing which shows the surroundings of the connection part of the image development apparatus and developer collection | recovery apparatus in a modification. It is sectional drawing which shows the modification of shutter shape. It is sectional drawing which shows the modification of shutter shape. It is sectional drawing which shows the modification of shutter shape. It is sectional drawing which shows the modification of shutter shape.

  Hereinafter, an embodiment of an image forming apparatus to which the developing system of the present invention is applied will be described with reference to the drawings. In the description of the drawings, the same elements will be denoted by the same reference symbols, without redundant description.

(Whole configuration of image forming apparatus)
As shown in FIG. 1, the image forming apparatus 1 includes a recording medium conveyance unit 10, a transfer unit 20, a photosensitive drum 30, four developing devices 100, and a fixing unit 40.

  The recording medium conveyance unit 10 accommodates a sheet P as a recording medium on which an image is finally formed. Further, the recording medium conveyance unit 10 conveys the sheet P onto the recording medium conveyance path. The paper P is stacked in the cassette. The recording medium conveyance unit 10 causes the sheet P to reach the secondary transfer area R at the timing when the toner image transferred to the sheet P reaches the secondary transfer area R.

  The transfer unit 20 conveys the toner image formed by the photosensitive drum 30 to a secondary transfer area R for secondary transfer onto the sheet P. The transfer unit 20 includes a transfer belt 21, suspension rollers 21a, 21b, 21c and 21d for suspending the transfer belt 21, a primary transfer roller 22 for holding the transfer belt 21 together with the photosensitive drum 30, and a transfer belt together with a suspension roller 21d. 21 and a secondary transfer roller 24 for holding the same.

  The transfer belt 21 is an endless belt which is circularly moved by the suspension rollers 21a, 21b, 21c and 21d. The primary transfer roller 22 is provided to press the photosensitive drum 30 from the inner peripheral side of the transfer belt 21. The secondary transfer roller 24 is provided to press the suspension roller 21 d from the outer peripheral side of the transfer belt 21. The transfer unit 20 may further include a belt cleaning device or the like for removing the toner attached to the transfer belt 21.

  The photosensitive drum 30 is an electrostatic latent image carrier on which an image is formed on the circumferential surface. The photosensitive drum 30 is made of, for example, an OPC (Organic PhotoConductor). The image forming apparatus 1 according to the present embodiment is an apparatus capable of forming a color image. In the image forming apparatus 1, for example, four photosensitive drums 30 are provided along the moving direction of the transfer belt 21 corresponding to each color of yellow, magenta, cyan, and black. As shown in FIG. 1, a charging roller 32, an exposure unit 34, a developing device 100, and a cleaning unit 38 are provided on the circumference of each photosensitive drum 30.

  The charging roller 32 uniformly charges the surface of the photosensitive drum 30 to a predetermined potential. The exposure unit 34 exposes the surface of the photosensitive drum 30 charged by the charging roller 32 in accordance with the image formed on the sheet P. As a result, the potential of the portion of the surface of the photosensitive drum 30 exposed by the exposure unit 34 changes, and an electrostatic latent image is formed. Toners are supplied to the four developing devices 100 from toner tanks 36 provided corresponding to the respective developing devices 100. The developing device 100 develops the electrostatic latent image formed on the photosensitive drum 30 by the toner to generate a toner image. The four toner tanks 36 are respectively filled with a replenishment developer in which yellow, magenta, cyan, and black toners and a carrier are mixed.

  The cleaning unit 38 recovers the toner remaining on the photosensitive drum 30 after the toner image formed on the photosensitive drum 30 is primarily transferred to the transfer belt 21. As the cleaning unit 38, for example, a configuration in which the remaining toner on the photosensitive drum 30 is removed by bringing a cleaning blade into contact with the circumferential surface of the photosensitive drum 30 can be employed. A discharging lamp for resetting the potential of the photosensitive drum 30 may be disposed between the cleaning unit 38 and the charging roller 32 in the rotational direction of the photosensitive drum 30 on the circumference of the photosensitive drum 30.

  The fixing unit 40 adheres and fixes the toner image secondarily transferred from the transfer belt 21 to the sheet P to the sheet P. The fixing unit 40 includes, for example, a heating roller 42 and a pressure roller 44. The heating roller 42 is a cylindrical member which can rotate around the rotation axis. Inside the heating roller 42, a heat source such as a halogen lamp is provided. The pressure roller 44 is a cylindrical member which can rotate around the rotation axis. The pressure roller 44 is provided to press the heating roller 42. On the outer peripheral surfaces of the heating roller 42 and the pressure roller 44, for example, a heat-resistant elastic layer such as silicone rubber is provided. The sheet P is fused and fixed to the sheet P by causing the sheet P to pass through a fixing nip portion which is a contact area between the heating roller 42 and the pressure roller 44.

  Further, the image forming apparatus 1 is provided with discharge rollers 52 and 54 for discharging the sheet P on which the toner image is fixed by the fixing unit 40 to the outside of the apparatus.

  Next, the operation of the image forming apparatus 1 will be described. An image signal of a recorded image is input to the image forming apparatus 1. The control unit of the image forming apparatus 1 uniformly charges the surface of the photosensitive drum 30 to a predetermined potential by the charging roller 32 based on the received image signal. Then, the control unit of the image forming apparatus 1 causes the exposure unit 34 to irradiate the surface of the photosensitive drum 30 with laser light to form an electrostatic latent image.

  The developing device 100 adjusts the toner and the carrier to a desired mixing ratio, and mixes and stirs the toner and the carrier. As a result, the developing device 100 uniformly disperses the toner and adjusts the developer such that an optimum charge amount is provided. The developer is carried on the developing roller 110. Then, when the developer is conveyed to a region facing the photosensitive drum 30 by the rotation of the developing roller 110, toner of the developer carried on the developing roller 110 is formed on the circumferential surface of the photosensitive drum 30. The electrostatic latent image is developed and developed. The toner image thus formed is primarily transferred from the photosensitive drum 30 to the transfer belt 21 in a region where the photosensitive drum 30 and the transfer belt 21 face each other. Toner images formed on the four photosensitive drums 30 are sequentially stacked on the transfer belt 21 to form one stacked toner image. Then, the laminated toner image is secondarily transferred onto the sheet P conveyed from the recording medium conveyance unit 10 in the secondary transfer area R where the suspension roller 21 d and the secondary transfer roller 24 face each other.

  The sheet P on which the laminated toner image is secondarily transferred is conveyed to the fixing unit 40. The layered toner image is fused and fixed to the sheet P by passing the sheet P between the heating roller 42 and the pressure roller 44 while applying heat and pressure. Thereafter, the sheet P is discharged to the outside of the image forming apparatus 1 by the discharge rollers 52 and 54. On the other hand, when the transfer belt 21 includes the belt cleaning device, after the laminated toner image is secondarily transferred to the sheet P, the toner remaining on the transfer belt 21 is removed by the belt cleaning device.

(Configuration of developing device)
The schematic configuration of the entire developing device 100 will be described. The developing device 100 uses, as a developer, a two-component developer composed of a toner and a carrier. Further, a so-called trickle development system is adopted for the developing device 100. In order to extend the life of the developer, the developing device 100 discharges the old developer from the developer discharge port, and supplies a new developer into the developer storage chamber.

  Specifically, the developing device 100 includes a developing roller 110, a first conveyance member (conveyance member) 120, and a second conveyance member (conveyance member) 130. The developing roller 110, the first conveying member 120, and the second conveying member 130 are provided in a developer storage chamber 160 formed by a case (case) 150 of the developing device 100.

  The developing roller 110 is a developer carrier that supplies toner to the electrostatic latent image formed on the circumferential surface of the photosensitive drum 30.

  The rotation of the developing roller 110 may cause air to be taken into the developer storage chamber 160. In this case, the pressure in the housing 150 is high. In order to release the pressure in the housing 150, the housing 150 may be provided with a pressure release hole 150a. The pressure release hole 150a may be covered by the filter 101 so that the developer is not discharged. The position where the pressure release hole 150a is provided is not limited to the position shown in FIG. 2 and can be provided at an appropriate position.

  The first transport member 120 and the second transport member 130 agitate the carrier of the magnetic material constituting the developer and the toner of the nonmagnetic material in the developer storage chamber 160 to frictionally charge the carrier and the toner. .

  The housing 150 is configured to include a first housing unit 151 and a second housing unit 152. The first housing 151 accommodates the developing roller 110 and the first conveyance member 120. The second housing 152 accommodates the second transport member 130.

  The first conveyance member 120 supplies the mixed and stirred developer to the developing roller 110. The first conveyance member 120 is configured to include a first support shaft 122 and a first conveyance wing 124. The first support shaft 122 is rotatably supported by the first housing 151. The first transfer wing 124 is provided on the outer peripheral surface of the first support shaft 122. The first transfer wing 124 has a helical inclined surface disposed along the longitudinal direction of the first support shaft 122.

  The second conveyance member 130 plays a role of mixing and stirring the developer to sufficiently charge the developer. The second transport member 130 transports the charged developer to the first transport member 120. Similar to the first conveyance member 120, the second conveyance member 130 includes the second support shaft 132 and the second conveyance wing 134. The second support shaft 132 is rotatably supported by the second housing 152. The second transfer wing 134 is provided on the outer peripheral surface of the second support shaft 132. The second transfer wing 134 has a helical inclined surface disposed along the longitudinal direction of the second support shaft 132.

  The first transport member 120 and the second transport member 130 are arranged side by side so that the first support shaft 122 and the second support shaft 132 are substantially parallel. The first casing 151 and the second casing 152 are provided adjacent to each other in the substantially vertical direction. In the present embodiment, the lower portion of the first casing 151 and the upper portion of the second casing 152 are configured by one member (hereinafter referred to as the “partition plate 106”). That is, the partition plate 106 also functions as a part of the first casing 151 and a part of the second casing 152. The partition plate 106 divides the first conveyance member 120 and the second conveyance member 130. The partition plate 106 is provided with a first opening 106 a and a second opening 106 b.

  The first opening 106 a delivers the developer from the inside of the first housing 151 to the inside of the second housing 152. The second opening 106 b delivers the developer from the second housing 152 to the first housing 151.

  The developer transported while being stirred by the second transport member 130 in the second housing portion 152 is sent into the first housing portion 151 via the second opening 106 b. The first conveyance wing 124 of the first conveyance member 120 conveys the developer while stirring it from the second opening 106 b side toward the first opening 106 a side. While the developer is being conveyed by the first conveyance member 120, a part of the developer moves to the circumferential surface of the developing roller 110. The remaining developer that has not moved to the circumferential surface of the developing roller 110 is fed into the second housing unit 152 through the first opening 106 a.

  The second housing portion 152 is provided with a developer supply port 152 a. In the second housing portion 152, a developer (toner and carrier) for replenishment is supplied through the developer replenishment port 152a.

  The first housing portion 151 is further provided with a developer discharge port H. The developer discharge port H discharges the developer degraded by the printing operation to the outside of the developing device 100 by using the fluctuation of the volume of the developer in the developer storage chamber 160. Specifically, a counter wing 126 and a discharge wing 128 are provided at an end of the first conveyance member 120 on the developer discharge port H side. The counter wing 126 is provided at a position between the first opening 106 a and the developer outlet H. The counter wing 126 is provided on the outer peripheral surface of the first support shaft 122. The counter wing 126 has a helical inclined surface disposed along the longitudinal direction of the first support shaft 122.

  The counter wing 126 transports the developer in the opposite direction to the first transport wing 124. That is, the counter wing 126 pushes back the developer directed from the first opening 106 a to the developer outlet H.

  The discharge wing 128 is provided closer to the developer discharge port H than the counter wing 126. The exhaust wing 128 is provided on the outer peripheral surface of the first support shaft 122. The discharge wing 128 has a helical inclined surface disposed along the longitudinal direction of the first support shaft 122. The discharge wing 128 transports the developer in the same direction as the first transport wing 124. That is, the discharge wing 128 transports the developer from the first opening 106 a toward the developer discharge port H.

  As described above, the counter wing 126 pushes the developer back to the first transport wing 124 side so that the developer in the developer storage chamber 160 does not move to the developer outlet H side. When the amount of developer in the developer storage chamber 160 increases, the developer gets over the counter blade 126. The developer having passed over the counter wing 126 is transported by the discharge wing 128 toward the developer outlet H.

  Here, the end on the side where the developer discharge port H is formed in the first housing portion 151 is formed in a substantially cylindrical shape. Hereinafter, a portion on the side where the developer discharge port H is formed in the first housing portion 151 is referred to as the insertion portion 155.

  Further, as shown in FIG. 3, the image forming apparatus 1 is provided with a developer recovery device 200 for recovering the developer. The developer recovery device 200 recovers the developer discharged from the developer discharge port H of the developing device 100 in a state where the developing device 100 is connected to the developer recovery device 200. As described above, in the present embodiment, the developing device 100 and the developer recovery device 200 are configured to collect the developer discharged from the developing device 100 in a state where the developing device 100 is connected to the developer recovery device 200. Constitute a developing system to be collected.

  Specifically, when the insertion portion 155 of the developing device 100 is inserted into the insertion hole 210 of the developer recovery device 200, the developing device 100 is connected to the developer recovery device 200. Hereinafter, the configuration around the connecting portion between the developing device 100 and the developer recovery device 200 (around the developer discharge port H) will be described.

  FIG. 4 and FIG. 5 are diagrams when the shutter 170 is in a closed state in a state where the developing device 100 is connected to the developer recovery device 200. As shown in FIGS. 4 and 5, an annular shutter 170 is attached to the insertion portion 155 of the developing device 100. The shutter 170 includes an annular shutter main body portion 171 and a convex portion 172 extending along the circumferential direction on the outer peripheral surface of the shutter main body portion 171. The shutter main body 171 is provided so as to surround the outer peripheral surface of the insertion portion 155.

  The shutter 170 is provided slidably with respect to the insertion portion 155 along the axial direction of the insertion portion 155 (the axial direction of the first support shaft 122). The shutter body portion 171 can cover the developer discharge port H provided in the insertion portion 155 by the slide. That is, the shutter 170 can adjust the opening area of the developer discharge port H by performing a sliding operation (opening and closing operation). In the state where the developing device 100 is not connected to the developer recovery device 200, the shutter 170 is slid by a mechanism (not shown) to close the developer discharge port H.

  When the developing device 100 is connected to the developer collection device 200, a part of the shutter 170 together with the insertion portion 155 is inserted into the insertion hole 210 of the developer collection device 200. When the developing device 100 is inserted into the developer recovery device 200, the convex portion 172 of the shutter 170 is in contact with the edge of the insertion hole 210. The shutter 170 covers the developer outlet H with the developing device 100 inserted into the developer recovery device 200. Although not shown in FIGS. 4 and 5, even if a seal member is provided so that the developer does not leak from the gap between the insertion hole 210 and the insertion portion 155 (shutter 170). Good.

  As shown in FIG. 5, a storage section (first storage section) 180 is provided inside the insertion section 155. In the present embodiment, the storage portion 180 is formed by recessing the inner wall of the insertion portion 155 outward. The developer discharge port H communicates with the storage section 180. The storage unit 180 temporarily stores the developer discharged to the outside of the developing device 100 through the developer discharge port H. The developer discharge port H discharges the developer in the reservoir 180 out of the developing device 100. Thus, the storage section 180 stores the developer discharged from the developer discharge port H at a position upstream of the developer discharge port H in the discharge direction.

  The storage unit 180 is provided with a storage amount detection sensor S that detects the storage amount of the developer stored in the storage unit 180.

  The developer recovery device 200 is provided with a drive mechanism 220 that slides (opens and closes) the shutter 170. The drive mechanism 220 adjusts the opening area of the developer discharge port H by opening and closing the shutter 170 in a state where the developing device 100 is connected to the developer collection device 200. Specifically, as shown in FIG. 4, the drive mechanism 220 includes a cam 221 and a drive unit 222 that controls the drive of the cam.

  The cam 221 is attached to the outer surface of the developer recovery device 200 and is rotated by the drive unit 222 about the rotation shaft 221 a. As shown in FIG. 4 and FIG. 6, the tip of the cam 221 biases the convex portion 172 of the shutter 170 by being rotated. Thereby, the shutter 170 is slid. The rotation of the cam 221 causes the shutter 170 to slide, and the opening area of the developer discharge port H changes as shown in FIGS. 5 and 7.

  The drive unit 222 includes a drive source (for example, a motor or the like) for driving the cam 221, and a control unit that controls the drive source. The drive source may be common to the drive source for rotating the first transport member 120 and the like, and may be provided exclusively for driving the cam 221. The drive unit 222 may be provided with a one-way clutch, an electromagnetic clutch, or the like in order to drive the cam 221.

  In the present embodiment, the drive mechanism 220 drives the cam 221 to switch the open / close state of the shutter 170 between the developer non-discharge mode and the developer discharge mode. In the developer non-discharge mode, as shown in FIGS. 4 and 5, in the state where the developing device 100 is connected to the developer recovery device 200, the opening area of the developer discharge port H is set to the first opening area. Mode. In the present embodiment, the first opening area is zero, and the developer outlet H is closed by the shutter 170. However, although the first opening area in the developer non-discharge mode is zero in this embodiment, the developer discharge port H may not be completely closed by the shutter 170.

  In the developer discharge mode, as shown in FIGS. 6 and 7, in the state where the developing device 100 is connected to the developer recovery device 200, the opening area of the developer discharge port H is larger than the first opening area. This is a mode in which the second opening area is large. In the present embodiment, the second opening area is the area of the developer discharge port H, and the developer discharge port H is not covered by the shutter 170 at all. However, the second opening area in the developer discharge mode may be smaller than the opening area of the developer discharge port H. That is, in the developer discharge mode, a part of the developer discharge port H may be covered by the shutter 170.

  As shown in FIG. 5, in the developer non-discharge mode, the developer discharge port H is closed by the shutter 170, so the developer is not discharged from the developer discharge port H. The developer transported to the developer outlet H beyond the counter wing 126 is stored in the storage section 180. As shown in FIG. 7, in the developer discharge mode, the shutter 170 slides, the developer discharge port H is opened, and the developer and the counter wing 126 accumulated in the storage section 180 are discharged. The developer conveyed toward the outlet H is discharged into the collection space L of the developer collection device 200.

Here, the rotational speed of the first conveyance member 120 and the second conveyance member 130 in the developer discharge mode is V1, and the rotation speed of the first conveyance member 120 and the second conveyance member 130 in the developer non-discharge mode is V2. . In this case, the following equation V1 ≦ V2
The rotational speeds of the first transport member 120 and the second transport member 130 are controlled to satisfy the following. Further, the drive mechanism 220 switches between the developer discharge mode and the developer non-discharge mode so as to satisfy the above equation. The rotation speed of the first conveyance member 120 or the like in the developer discharge mode is made slower than the rotation speed of the first conveyance member 120 in the developer non-discharge mode, so that the developer is taken into the housing 150 by the rotation of the developing roller 110 The amount of air can be suppressed, and the flow of air generated in the housing 150 can be suppressed. In addition, although V1 and V2 set it as the rotational speed of the 1st conveyance member 120 and the 2nd conveyance member 130, you may use the rotational speed of any one of the 1st conveyance member 120 and the 2nd conveyance member 130. FIG.

  In the developer non-discharge mode, when storage of the developer exceeding the reference value is detected by the storage amount detection sensor S, the drive mechanism 220 switches the shutter 170 from the developer discharge mode to the developer discharge mode. As described above, the drive mechanism 220 may slide (open and close) the shutter 170 based on the detection result of the storage amount detection sensor S.

  When the developing device 100 changes from the driving state to the driving stop state, the driving mechanism 220 has an opening area of the developer discharge port H more than the opening area of the developer discharge port H immediately before the driving of the developing device 100 is stopped. The shutter 170 may be slid to be large. That is, the driving mechanism 220 may switch the shutter 170 from the non-developer discharging mode to the developer discharging mode when the developing device 100 changes from the driving state to the driving stop state.

  The driving mechanism 220 has a shutter such that the opening area of the developer discharge opening H is smaller than the opening area of the developer discharge opening H when the driving of the developing device 100 is stopped when the developing device 100 starts driving. You may slide 170. That is, the driving mechanism 220 may switch the shutter 170 from the developer discharging mode to the developer non-discharging mode when the developing device 100 changes from the driving stop state to the driving state.

  A plurality of developing devices 100 may be connected to the developer recovery device 200. In the present embodiment, four developing devices 100 corresponding to the respective colors of yellow, magenta, cyan and black may be connected to the developer recovery device 200. In this case, the shutter 170 and the drive mechanism 220 are provided for each of the plurality of developing devices 100. And each of the plurality of drive mechanisms 220 can slide the respective shutters 170 simultaneously or separately.

  The present embodiment is configured as described above, and the developing system can open and close the shutter 170 even when the developing device 100 is connected to the developer recovery device 200. That is, the opening area of the developer discharge port H can be adjusted in accordance with the operating state of the developing device 100, and the opening area of the developer discharge port H can be adjusted in accordance with various conditions. As described above, the development system can suppress the excessive discharge of the developer from the developing device 100 due to the flow of air by adjusting the opening area of the developer discharge port H.

  In the developing device 100, a storage portion 180 for storing the developer is provided at a position upstream of the developer discharge port H in the discharge direction. In this case, the developer can be temporarily stored in the storage unit 180 before being discharged from the developer discharge port H. As a result, even when the developer discharge port H is closed by the shutter 170 (small opening area), the developer can be prevented from being clogged in the housing 150 of the developing device 100. Thereby, it can suppress that rotation of the 1st conveyance member 120 grade is inhibited.

  The drive mechanism 220 can switch the open / close state of the shutter 170 between the developer non-discharge mode and the developer discharge mode. In this case, even when the developing device 100 is connected to the developer recovery device 200, the open / close state of the shutter 170 can be switched to the two modes, so the developer is excessively discharged from the developing device 100. Can be suppressed.

  Assuming that the rotation speed of the conveyance member in the developer discharge mode is V1, and the rotation speed of the conveyance member in the developer non-discharge mode is V2, V1 ≦ V2 is satisfied. Here, when the rotational speeds of the first conveying member 120 and the second conveying member 130 are high, a large amount of air is taken into the developing device 100, whereby the internal pressure of the developing device 100 is increased, and the developer is carried by the air flow. It becomes easy for the developer to be excessively discharged from the discharge port H. For this reason, when the rotation speed of the first conveyance member 120 or the like is fast, by reducing the opening area of the developer discharge port H, excessive discharge of the developer from the developing device 100 can be suppressed.

  The drive mechanism 220 opens and closes the shutter based on the detection result of the storage amount detection sensor S. In this case, the drive mechanism 220 can discharge the developer according to the storage amount of the developer, and clogging of the developer in the casing 150 of the developing device 100 is suppressed. Thereby, it can suppress that rotation of the 1st conveyance member 120 grade is inhibited.

  The driving mechanism 220 opens and closes the shutter 170 so that the opening area of the developer discharge opening H becomes larger than the opening area of the developer discharge opening H immediately before the stop of the driving when the developing device 100 stops driving. Let When the developing device 100 stops driving, the internal pressure of the developing device 100 is lower than that during driving. For this reason, excessive discharge of the developer on the air flow is less likely to occur. Therefore, the developing system can discharge the old developer while suppressing the excessive discharge of the developer by increasing the opening area of the developer discharge port H when the driving of the developing device 100 is stopped.

  The driving mechanism 220 has a shutter such that the opening area of the developer discharge opening H is smaller than the opening area of the developer discharge opening H when the driving of the developing device 100 is stopped when the developing device 100 starts driving. Open and close 170. When the developing device 100 starts driving, the internal pressure of the developing device 100 becomes higher than when driving is stopped. For this reason, it becomes easy for the developer to be discharged excessively due to the flow of air. Therefore, the developing system can suppress excessive discharge of the developer by reducing the opening area of the developer discharge port H when the developing device 100 starts driving.

  The housing 150 is provided with a pressure release hole 150a with a filter 101a. In this case, an increase in internal pressure of the housing 150 of the developing device 100 can be suppressed, and excessive discharge of the developer from the developing device 100 can be suppressed.

  A plurality of developing devices 100 are connected to the developer recovery device 200. Then, each of the drive mechanisms 220 provided in the plurality of developing devices 100 causes the respective shutters 170 to open and close each other or individually. As described above, even when the plurality of developing devices 100 are connected to the developer recovery device 200, the developing system can appropriately open and close the shutter 170.

  Although the drive mechanism 220 is provided in the developer recovery device 200 in the above embodiment, the drive mechanism 220 may be provided in the developing device 100. Further, when the drive mechanism 220 slides the shutter 170 to open the developer discharge port H in the developer discharge mode, various kinds of detection results such as the rotational speed of the first conveyance member 120 and the detection result of the storage amount detection sensor S Depending on the conditions, the size of the opening area may be adjusted. Moreover, it is not essential that the storage unit 180 is provided, and the storage unit 180 may not be provided. In addition, the drive mechanism 220 may slide the shutter 170 by a mechanism other than the mechanism using the cam 221.

(Modification)
Next, a modification of the developing system will be described. The present modification is different from the above embodiment in the configuration of the storage unit 180 and the configuration of the shutter 170. Hereinafter, differences from the embodiment will be mainly described, and the same components as those of the embodiment will be denoted by the same reference numerals and detailed description thereof will be omitted. As shown in FIG. 8, in the developing device 100 </ b> A in this modification, a storage section 180 </ b> A is provided at the tip of the insertion section 155. That is, the housing 150 is provided with a storage portion 180A in addition to the first housing portion 151 and the second housing portion 152 for housing the first transport member 120 and the second transport member 130. The storage section 180A is a cylindrical member extending in the vertical direction. In addition, the insertion portion 155 is provided with a case opening 151b communicating the inside of the storage portion 180A with the inside of the insertion portion 155.

  The developer conveyed in the insertion portion 155 toward the case opening 151b enters the storage portion 180A through the case opening 151b, and is discharged from the lower opening of the storage portion 180A to the outside of the developing device 100A. Be done. Hereinafter, the opening on the lower end side of the storage section 180A is referred to as a developer discharge port H1. A shutter 170A that covers the developer discharge port H1 so as to be capable of opening and closing is provided at the lower end portion of the storage section 180A. The shutter 170A is a flat member, and is attached to the lower end of the storage section 180A so as to be rotatable about an axis J (see FIGS. 8 to 10).

  The developing device 100A also includes a drive mechanism 220A that opens and closes the shutter 170A. In the present modification, the drive mechanism 220A biases the shutter 170A toward the lower end portion of the storage section 180A by the force of the spring. The shutter 170A is pressed against the lower end portion of the storage section 180A by the drive mechanism 220A, thereby closing the developer discharge port H.

  When the developer discharge port H1 is closed by the shutter 170A, the developer that has entered the storage portion 180A from the insertion portion 155 via the case opening 151b is collected on the shutter 170A. The drive mechanism 220A rotates the shutter 170A by its own weight of the developer accumulated on the shutter 170A. Here, the driving mechanism 220A rotates the shutter 170A when the developer of a predetermined amount (predetermined weight) is accumulated on the shutter 170A.

  In this modification, in addition to the insertion portion 155, a portion including the storage portion 180A, the shutter 170A, and the drive mechanism 220A is inserted into the insertion hole 210A of the developer recovery device 200A. That is, the storage unit 180A and the shutter 170A are located in the collection space L of the developer collection device 200A.

  For example, as shown in FIG. 8, when the developer discharge port H1 is closed by the shutter 170A, the developer G transported by the discharge wing 128 and entering the storage portion 180A from the case opening 151b is , Accumulate on the shutter 170A. When a predetermined amount of developer G is accumulated on the shutter 170A, as shown in FIG. 9, the drive mechanism 220A rotates the shutter 170A downward about the axis J by the weight of the developer G. As a result, the developer G in the storage section 180A is discharged into the collection space L of the developer collection device 200A.

  When the developer G in the storage section 180A is discharged, as shown in FIG. 10, the drive mechanism 220A returns the shutter 170A to the original position (position where the developer discharge port H1 is closed) by the force of the spring. Back to. As described above, in the present embodiment, the developing device 100A and the developer collection device 200A are configured such that the developer collected from the developing device 100A with the developing device 100A connected to the developer collection device 200A. Constitute a developing system to be collected.

  Thus, the shutter 170A adjusts the opening area of the developer discharge port H1 by rotating (opening and closing operation). In addition, the driving mechanism 220A rotates the shutter 170A (opens and closes) by the weight of the developer and the force of the spring to make the developer discharge port H1 close with the shutter 170A (state of FIG. 8). It is possible to switch between the non-discharge mode and the developer discharge mode in which the developer discharge port H1 is in the open state (the state of FIG. 9).

  As described above, the drive mechanism 220A in this modification operates the shutter 170A by the weight of the developer accumulated on the shutter 170A. In this case, a drive source for driving the shutter 170A is unnecessary, and the development system can be simplified.

  The drive mechanism 220A in the present modification is not limited to rotating the shutter 170A by the weight of the developer and the force of the spring. The drive mechanism 220A in this modification may rotate the shutter 170A by a drive source such as a motor as in the developer recovery device 200 of the embodiment. In this case, the drive mechanism 220A can open and close the shutter 170A at the same timing as the drive mechanism 220 in the embodiment, for example, at the start of driving of the developing device 100.

  The storage unit 180A, the shutter 170A, and the drive mechanism 220A are not limited to being provided in the developing device 100A, and may be provided in the developer recovery device 200. In this case, the insertion portion 155 is developed so that the case opening 151b of the insertion portion 155 faces the inside of the upper opening edge of the storage portion (second storage portion) 180A provided in the developer recovery device 200. It is inserted into the agent recovery device 200A. Alternatively, the storage unit 180A, the shutter 170A, and the drive mechanism 220A may be provided as separate members from the developing device 100A and the developer recovery device 200A.

(Modified example of shutter shape)
In the above-mentioned modification, although the case where shutter 170A was flat-like was explained to an example, the shape of a shutter is not limited to flat-like. For example, as in the shutters 170B and 170C shown in FIGS. 11 and 12, the upstream side surface of the shutters 170B and 170C in the developer discharge direction (surface on the storage section 180A side) is formed in a tapered shape. It is also good. Here, as shown in FIG. 11, in the state where the developer discharge port H1 is closed by the shutter 170B, the surface on the storage portion 180A side of the shutter 170B is shaped to be recessed downward. . Further, as shown in FIG. 12, in the state where the developer discharge port H1 is closed by the shutter 170C, the surface on the storage section 180A side of the shutter 170C protrudes toward the upper side (the storage section 180A side) It has a shape.

  For example, as in the shutters 170D and 170E shown in FIGS. 13 and 14, the upstream side surface (surface on the storage section 180A side) of the shutters 170D and 170E in the developer discharge direction is formed in a bowl shape. It is also good. Here, as shown in FIG. 13, in the state where the developer discharge port H1 is closed by the shutter 170D, the surface on the storage section 180A side of the shutter 170D is shaped to be recessed downward. . In addition, as shown in FIG. 14, in a state where the developer discharge port H1 is closed by the shutter 170E, the surface on the storage section 180A side of the shutter 170E bulges toward the upper side (storage section 180A side) It has become.

  Like the shutters 170A to 170E, various shapes can be adopted as the shape of the shutter. For example, the shape of the shutter may be selected according to the viscosity of the developer (ease of dropping of the developer from the shutter) or the like. As described above, since various shapes can be adopted as the shape of the shutter, the developer can be appropriately discharged, for example, the developer remaining on the shutter can be reduced when the shutter is opened.

  100, 100A: developing device (developing system), 101: filter, 120: first conveying member (conveying member), 130: second conveying member (conveying member), 150: case (case), 150a: pressure relief hole 170, 170A to 170E: Shutter, 180, 180A: Reservoir (first reservoir, second reservoir) 200, 200A: Developer recovery device (developing system), 220, 220A: Drive mechanism, H, H1 ... Developer outlet, L ... recovery space, S ... storage amount detection sensor.

Claims (13)

A developing system comprising a developing device and a developer recovery device, wherein the developer discharged from the developing device is recovered to the developer recovery device in a state where the development device is connected to the developer recovery device,
The developing device is
A case for containing the developer;
A shutter that opens and closes,
Equipped with
The developing device or the developer recovery device includes a drive mechanism that opens and closes the shutter.
The case is provided with a developer discharge port for discharging the developer in the case to the developer recovery device.
The shutter can adjust the opening area of the developer discharge port by performing an opening and closing operation,
The developing system adjusts the opening area of the developer discharge port by opening and closing the shutter in a state where the developing device is connected to the developer recovery device. The case is provided with a first storage portion for storing the developer discharged from the developer discharge port at a position upstream of the developer discharge port in the discharge direction.
The developing system according to claim 1, wherein the developer discharge port discharges the developer in the first storage section to the developer recovery device. A developing system comprising a developing device and a developer recovery device, wherein the developer discharged from the developing device is recovered to the developer recovery device in a state where the development device is connected to the developer recovery device,
The developer recovery device is
A second storage unit for storing the developer discharged from the developing device connected to the developer recovery device;
A shutter that opens and closes,
A drive mechanism for opening and closing the shutter;
Equipped with
The second storage portion is provided with a developer discharge port for discharging the developer in the second storage portion into a collection space of the developer collection device,
The shutter can adjust the opening area of the developer discharge port by performing an opening and closing operation,
The developing system adjusts the opening area of the developer discharge port by opening and closing the shutter in a state where the developing device is connected to the developer recovery device. The drive mechanism is configured to open and close the shutter.
A developer non-discharge mode in which an opening area of the developer discharge port is a first opening area in a state where the developing device is connected to the developer collection device;
A developer discharge mode in which an opening area of the developer discharge port is a second opening area larger than the first opening area in a state where the developing device is connected to the developer collection device;
The development system according to any one of claims 1 to 3, which is switchable. The developing device includes a conveying member for circulating the developer in the developing device.
Assuming that the rotational speed of the transport member in the developer discharge mode is V1, and the rotational speed of the transport member in the developer non-discharge mode is V2.
V1 ≦ V2
The development system according to claim 4, wherein   The developing system according to any one of claims 1 to 5, wherein the driving mechanism opens and closes the shutter by a weight of the developer accumulated on the shutter. A storage amount detection sensor for detecting the storage amount of the developer in the first storage section;
The developing system according to claim 2, wherein the drive mechanism opens and closes the shutter based on a detection result of the storage amount detection sensor. A storage amount detection sensor for detecting the storage amount of the developer in the second storage section;
The developing system according to claim 3, wherein the drive mechanism opens and closes the shutter based on a detection result of the storage amount detection sensor.   The driving mechanism is configured such that, when the developing device stops driving, the opening area of the developer discharge port is larger than the opening area of the developer discharge port immediately before the driving of the developing device is stopped. The development system according to any one of claims 1 to 5, wherein the shutter is operated.   The driving mechanism is configured such that, when the developing device starts driving, the opening area of the developer discharge port is smaller than the opening area of the developer discharge port when the driving of the developing device is stopped. The development system according to any one of claims 1 to 5, wherein the shutter is operated.   The development system according to any one of claims 1 to 10, wherein an upstream surface of the developer in the discharge direction in the shutter is formed in a tapered shape, a bowl shape, or a flat plate shape. The case is provided with a pressure relief hole for adjusting the pressure in the case,
The development system according to claim 1, wherein the pressure release hole is covered by a filter. A plurality of the developing devices are connected to the developer recovery device,
The shutter and the drive mechanism are provided to a plurality of the developing devices, respectively.
The developing system according to any one of claims 1 to 5, wherein each of the plurality of drive mechanisms opens and closes each shutter simultaneously or separately.