DEVELOPING CARTRIDGE

BACKGROUND

An electronic imaging device is a device that forms an image on a recording material through the principle of electrophotographic imaging, for example, an electrophotographic copier, a laser printer, an electrophotographic printer (such as a laser printer and an LED printer, etc.), a fax machine, and a word processor. The imaging device usually includes a developing cartridge and a drum cartridge. The developing cartridge supplies a developer to the drum cartridge that has been formed with an electrostatic latent image. A visible developer image corresponding to the electrostatic latent image is formed on a pho to sensitive drum of the drum cartridge. Then, the developer image is transferred onto a recording medium through transferring, and finally the developer image is fixed onto the recording medium through fixing. Finally, the recording medium is discharged from an image forming apparatus to complete the printing operation.

SUMMARY

Disclosed herein is a developing cartridge, comprising: a housing; a developer roller supported by the housing and configured to rotate about an axis of the developer roller; and a coupling gear located on a first side of the housing, and configured to rotate by receiving a driving force; a transmission rod configured to move in response to a rotation of the coupling gear, a first part of the transmission rod located on the first side of the housing; a first protrusion movably mounted on a second side of the housing, and configured to move in response to a movement of the transmission rod; and a second protrusion on the first side of the housing, extending toward the second side of the housing, and the second protrusion comprising a guide surface configured to cause the transmission rod to move toward the second side of the housing in response to the rotation of the coupling gear.

In an aspect, the guide surface is inclined with respect to the axis of the developer roller.

In an aspect, the housing comprises a plate on the first side of the housing and supporting the second protrusion, and an included angle between an extending direction of the guide surface and an extending direction of the plate is an obtuse angle.

In an aspect, the second protrusion further comprises an urging surface arranged adjacent to the guide surface, and the guide surface is inclined relative to the urging surface.

In an aspect, the second protrusion further comprises an urging surface, one end of the guide surface is adjacent to the plate, and another end of the guide surface is adjacent to the urging surface.

In an aspect, the extending direction of the plate is parallel to an extending direction of the urging surface.

In an aspect, the developing cartridge further comprises a compression spring mounted on the transmission rod and configured to cause the transmission rod to move toward the second side of the housing. One end of the compression spring abuts the housing, and another end of the compression spring abuts the transmission rod, and the compression spring is configured to be compressed in response to the rotation of the coupling gear.

In an aspect, a second part of the transmission rod is located on the second side of the housing, and the first protrusion is mounted on the second part of the transmission rod and movable relative to the transmission rod.

In an aspect, the first protrusion is configured to move in a direction different from a moving direction of the transmission rod, under a driving force from the transmission rod.

In an aspect, the developing cartridge further comprises a transmission gear on the first side of the housing and configured to rotate in response to the rotation of the coupling gear. The second protrusion is on the transmission gear.

In an aspect, the guide surface of the second protrusion is configured to force the transmission rod to move by contacting the transmission rod.

In an aspect, the developing cartridge further comprises an agitator inside the housing configured to agitate a developer. The transmission gear is mounted at an end of the agitator.

In an aspect, the developing cartridge further comprises two idler gears between the transmission gear and the coupling gear.

In an aspect, the developing cartridge further comprises an electrode electrically connected to the developer roller. The electrode has an electrical contact surface on the second side of the housing, and the electrical contact surface is between the developer roller and the transmission rod.

In an aspect, the housing comprises a container configured to accommodate a developer, and the transmission rod is outside the container.

Also disclosed herein is a developing cartridge, comprising: a housing; a developer roller supported by the housing and configured to rotate about an axis of the developer roller; a developer feeding roller supported by the housing and configured to rotate about an axis of the developer feeding roller; and a coupling gear on a first side of the housing, and configured to rotate by receiving a driving force; a transmission rod configured to move in response to a rotation of the coupling gear, a first part of the transmission rod located on the first side of the housing; an elastic member between the housing and the transmission rod, configured to cause the transmission rod to move; a first protrusion on a second side of the housing and configured to move in response to a movement of the transmission rod; and an electrode electrically connected to the developer roller or the developer feeding roller and having an electrical contact surface on the second side of the housing. The electrical contact surface is between the developer roller and the transmission rod.

In an aspect, the first protrusion is integrally molded with the transmission rod.

In an aspect, the developing cartridge further comprises a transmission gear configured to move the transmission rod. The elastic member is located on the first side of the housing. The transmission gear is configured to cause the transmission rod to move against the elastic member. When the transmission gear is disengaged from the transmission rod, the elastic member is configured to move the transmission rod.

In an aspect, the elastic member is on the first side of the housing, the transmission gear, the transmission rod and the first protrusion are sequentially arranged along the axis of the developer roller.

In an aspect, a protruding portion is provided on the transmission rod, and the elastic member is mounted on the protruding portion.

In an aspect, the housing comprises a container configured to accommodate a developer, the transmission rod is located outside the container, and the elastic member is between the first side of the housing and the second side of the housing.

Further disclosed herein is a developing cartridge, comprising: a housing; a developer roller supported by the housing and configured to rotate about an axis of the developer roller; and a coupling gear located on a first side of the housing, and configured to rotate by receiving a driving force; a transmission rod configured to move in response to a rotation of the coupling gear, a first part of the transmission rod located on the first side of the housing, and a second part of the transmission rod located on a second side of the housing; and a first protrusion on the second side of the housing and configured to move in response to a movement of the transmission rod. The transmission rod is movably mounted on the housing, and the transmission rod is restricted to rotate about an axis parallel to the axis of the developer roller.

In an aspect, the first protrusion is integrally molded with the transmission rod.

In an aspect, the developing cartridge further comprises a second protrusion on the first side of the housing, extending toward the second side of the housing, and configured to cause the transmission rod to move relative to the housing in response to the rotation of the coupling gear.

In an aspect, the developing cartridge further comprises an elastic member mounted on the transmission rod and configured to cause the transmission rod to move. One end of the elastic member abuts the housing and another end of the elastic member abuts the transmission rod.

In an aspect, a protruding portion is provided on the transmission rod, and the elastic member is mounted on the protruding portion.

In an aspect, the housing comprises a container configured to accommodate a developer, the transmission rod is located outside the container, and the developing cartridge further comprises an elastic member between the first side of the housing and the second side of the housing.

BRIEF DESCRIPTION OF FIGURES

FIG. 1 is a schematic view of a developing cartridge according to Embodiment 1;

FIG. 2 is an exploded schematic view of a driving side of the developing cartridge according to Embodiment 1;

FIG. 3 is an exploded schematic view of the developing cartridge according to Embodiment 1 from an angle;

FIG. 4 is an exploded schematic view of the developing cartridge according to Embodiment 1 from another angle;

FIG. 5 is a schematic view of an agitator shaft and an agitator gear of the developing cartridge according to Embodiment 1;

FIG. 6 is a schematic view of a toggle member of the developing cartridge according to Embodiment 1;

FIG. 7 is a schematic view of a developing cartridge according to Embodiment 2 from an angle;

FIG. 8 is an exploded schematic view of a driving side of the developing cartridge according to Embodiment 2;

FIG. 9 is an exploded schematic view showing that an agitator gear is disassembled from the developing cartridge according to Embodiment 2;

FIG. 10 is an exploded schematic view showing that a transmission component, an agitator shaft and the agitator gear are disassembled from the developing cartridge according to Embodiment 2;

FIG. 11 is an exploded schematic view of the developing cartridge according to Embodiment 2 from an angle;

FIG. 12 is a schematic view of the assembly relationship of the transmission component, the agitator shaft and the agitator gear according to Embodiment 2;

FIG. 13 is a schematic view of the developing cartridge according to Embodiment 2 from another angle;

FIG. 14 is an exploded schematic view of a conductive side of the developing cartridge according to Embodiment 2;

FIG. 15 is a schematic view of a developing cartridge according to Embodiment 3 from an angle;

FIG. 16 is an exploded schematic view of a driving side of the developing cartridge according to Embodiment 3;

FIG. 17 is an exploded schematic view of the driving side of the developing cartridge according to Embodiment 3, in which a driving portion is rotated between a pair of driven portions;

FIG. 18 is an exploded schematic view showing that a transmission gear and a first transmission component are disassembled from the developing cartridge according to Embodiment 3;

FIG. 19 is an exploded schematic view showing that the transmission gear and the first transmission component are disassembled from the developing cartridge according to Embodiment 3 after an upper cover of a housing is removed;

FIG. 20 is an exploded schematic view showing that a detection structure is disassembled from the developing cartridge according to Embodiment 3;

FIG. 21 is an exploded schematic view of the detection structure of the developing cartridge according to Embodiment 3 from an angle;

FIG. 22 is a schematic view of the developing cartridge according to Embodiment 3 from another angle;

FIG. 23 is a schematic view of the developing cartridge according to Embodiment 3 after the upper cover of the housing is removed;

FIG. 24 is an exploded schematic view of the detection structure of the developing cartridge according to Embodiment 3 from another angle;

FIG. 25 is a schematic view of the developing cartridge according to Embodiment 3 before a second transmission component pushes a toggle member;

FIG. 26 is a schematic view of the developing cartridge according to Embodiment 3 when the second transmission component pushes the toggle member;

FIG. 27 is a schematic view of the developing cartridge according to Embodiment 3 when the second transmission component no longer pushes the toggle member;

FIG. 28 is a schematic view of a developing cartridge according to Embodiment 4;

FIG. 29 is an exploded schematic view of the developing cartridge according to Embodiment 4 after a driving side protective cover is disassembled from the developing cartridge;

FIG. 30 is an exploded schematic view of a power assembly on a driving side of the developing cartridge according to Embodiment 4;

FIG. 31 is a schematic view of a detection assembly according to Embodiment 4 from an angle;

FIG. 32 is an exploded schematic view of the detection assembly according to Embodiment 4;

FIG. 33 is a schematic view of a first transmission component according to Embodiment 4;

FIG. 34 is a schematic view of the detection assembly according to Embodiment 4 from another angle;

FIG. 35 is a schematic view of a second transmission component according to Embodiment 4 when it abuts against pushes an urging portion;

FIG. 36 is a schematic view of the second transmission component according to Embodiment 4 when it abuts against a main body portion of the first transmission component;

FIG. 37 is a schematic view of the second transmission component according to Embodiment 4 when it abuts against a guide surface of a second urging portion;

FIG. 38 is a schematic view of the second transmission component according to Embodiment 4 when it abuts against an urging surface of the second urging portion;

FIG. 39 is a schematic view according to Embodiment 4 at a detection termination position;

FIG. 40 is a schematic view of the developing cartridge according to Embodiment 4 when the toggle member is located at a non-toggle position;

FIG. 41 is a schematic view of the developing cartridge according to Embodiment 4 when the toggle member is located at a toggle position; and

FIG. 42 is an exploded schematic view of the toggle member and a second elastic member at a right end of the developing cartridge according to Embodiment 4.

DETAILED DESCRIPTION

An electronic imaging device (e.g., a printer) may include a mechanism for detecting the presence or characteristics of a consumable part (e.g., a developing cartridge). The consumable part may have an electronic or mechanical component that the electronic imaging device may sense. For example, the electronic or mechanical component may cause a physical movement of the mechanism when the consumable part is installed into the electronic imaging device.

Embodiment 1

First, as shown in FIGS. 1 to 6, a developing cartridge of the present disclosure is detachably mounted in a drum assembly (not shown), and may be detachably mounted in an image forming apparatus together with the drum assembly. The developing cartridge includes a housing 1, a developer roller 2, a handle 3, a coupling gear 4, an agitator shaft 7, a developer feeding roller 9, an electrode 21 and a toggle member 22. The housing 1 has a developer accommodating portion 1a that can accommodate a developer, and a first hole 17 and a second hole 27 that are provided at left and right ends, respectively. The first hole 17 and the second hole 27 are through holes formed in left and right end side walls (“left end side” interchangeably referred to as “first side” and “right end side” interchangeably referred to as “second side”) of the housing 1, respectively. The developer roller 2 and the developer feeding roller 9 are rotatably supported by the housing 1. The developer roller 2 may rotate about an axis of the developer roller extending in a left and right direction, and the developer feeding roller 9 may rotate about an axis of the developer feeding roller extending in the left and right direction. At least a part of the agitator shaft 7 is located in the developer accommodating portion 1a of the housing 1. The developer roller 2, the developer feeding roller 9, and the agitator shaft 7 (to be described in detail below) of the developing cartridge are defined to be sequentially arranged in a front and rear direction. The developer roller 2 is arranged on a front end side of the developing cartridge in the front and rear direction. The handle 3 is arranged on a rear end side of the developing cartridge in the front and rear direction. The front and rear direction of the developing cartridge is perpendicular to the left and right direction described above. The side of the developing cartridge where the coupling gear 4 is located is a driving side 10 of the developing cartridge, and the driving side 10 is a left end side of the housing 1 in the left and right direction. The electrode 21 is configured to span left and right ends of the housing 1. The electrode 21 is electrically connected to the developer roller 2 and the developer feeding roller 9. The electrode 21 has an electrical contact surface 21a, and the electrical contact surface 21a may be in electrical contact with a power supply component in the image forming apparatus. The side where the electrical contact surface 21a is located is provided on a conductive side 20 of the developing cartridge, and the driving side 10 and the conductive side 20 are located at two side ends of the housing 1 in the left and right direction, respectively. The toggle member 22 is used to toggle a detection body (not shown) in the image forming apparatus, so as to output to the image forming apparatus information such as whether the developing cartridge is a new cartridge or not or page yield of the developing cartridge. That is to say, the toggle member 22 as a detected body may be detected by the image forming apparatus.

The driving side 10 of the developing cartridge includes a coupling gear 4, a developer roller gear 5, a developer feeding roller gear (not shown) and an agitator gear 6. The coupling gear 4 may be engaged with a driving shaft in the image forming apparatus to receive a driving force. The developer roller gear 5 and the developer feeding roller gear are both in contact with and engaged with the coupling gear 4, and can drive the developer roller 2 and the developer feeding roller 9 to rotate, respectively. The agitator gear 6 is also engaged with the coupling gear 4 and can follow the rotation of the coupling gear 4 to rotate. The left end of the agitator shaft 7 is connected to the agitator gear 6, and may be driven to rotate by the agitator gear 6. The driving side 10 of the developing cartridge is further provided with a driving side protective cover 19. The driving side protective cover 19 is arranged to cover at least a part of the coupling gear 4, the developer roller gear 5, the developer feeding roller gear and the agitator gear 6. The driving side 10 of the developing cartridge is further provided with a storage component 11 and a storage component mounting frame 12 supporting the storage component 11. The storage component 11 stores relevant information of the developing cartridge and may establish a communication connection with the image forming apparatus. The storage component mounting frame 12 is detachably mounted on the driving side protective cover 19. Optionally, the storage component mounting frame 12 may also be configured to be detachably mounted on the housing 1, which is not limited. The agitator shaft 7 further includes a rod portion 8 extending axially (in the left and right direction) outward from the left end of the agitator shaft 7. A first transmission protrusion 8a and a second transmission protrusion 8b are formed extending radially outward on the outer peripheral surface of an end of the rod portion 8 close to the driving side 10. The first transmission protrusion 8a is arranged in the center closer to the agitator shaft 7 relative to the second transmission protrusion 8b in the left and right direction. Preferably, one first transmission protrusion 8a is provided, one pair of second transmission protrusions 8b are provided, and the pair of second transmission protrusions 8b are arranged at an interval along the outer circumferential surface of the rod portion 8 in the rotational direction of the rod portion 8. The agitator gear 6 includes one gear part 6c engaged with the coupling gear 4 and a pair of coupling portions 6b coupled with the second transmission protrusions 8b. The coupling portion 6b is a groove formed on the inner surface of the agitator gear 6. The second transmission protrusion 8b may be coupled with the coupling portion 6b of the agitator gear 6 to drive the agitator shaft 7 to rotate. The inner surface of the agitator gear 6 further includes a spiral groove 6a extending in the left and right direction. The spiral groove 6a is arranged on the right end closer to the developing cartridge in the left and right direction relative to the coupling portion 6b. The first transmission protrusion 8a on the rod portion 8 may cooperate with the spiral groove 6a and slide on the spiral groove 6a. The first transmission protrusion 8a can force the agitator shaft 7 to move in the left and right direction by means of an axial force generated by sliding on the spiral groove 6a. Specifically, the agitator shaft 7 has a first position and a second position, and the agitator shaft 7 in the first position is closer to the left end of the developing cartridge relative to the agitator shaft 7 in the second position. That is to say, when the agitator shaft 7 moves from the first position toward the second position, the agitator shaft 7 as a whole moves from the left end to the right end. When the agitator shaft 7 is in the first position, the second transmission protrusion 8b is not coupled with the coupling portion 6b so that the agitator gear 6 cannot drive the agitator shaft 7 to rotate. When the agitator shaft 7 is in the second position, the second transmission protrusion 8b is coupled with the coupling portion 6b, so that the agitator gear 6 can drive the agitator shaft 7 to rotate. When the developing cartridge is a new developing cartridge, the agitator shaft 7 is in the first position.

The conductive side 20 of the developing cartridge includes a toggle member 22, a transmission component 23, a holding component 24 and a conductive side protective cover 29, and the conductive side protective cover 29 is mounted on a conductive side 20 of the developing cartridge in such a manner as to cover at least a part of the transmission component 23, wherein the transmission component 23 is sleeved on a right end portion of the agitator shaft 7 and coaxially arranged with the agitator shaft 7, and at least a part of the transmission component 23 is accommodated in the second hole 27 of the housing 1, and is movably supported by the housing 1. Specifically, the transmission component 23 may move in the left and right direction relative to the housing 1. The transmission component 23 may be composed of a single component or a plurality of components. Preferably, one transmission component 23 is provided, and the transmission component 23 is sequentially provided with a first restricting portion 23b, a second restricting portion 23c, and a pushing portion 23a from left to right. Preferably, the first restricting portion 23b, the second restricting portion 23c, and the pushing portion 23a are all configured as protrusions formed on the transmission component 23, wherein the pushing portion 23a may push the detection body in the image forming apparatus to be detected by the image forming apparatus. Preferably, there is a pair of first restricting portions 23b, and the pair of first restricting portions 23b are arranged at an interval along the rotational direction of the transmission component 23 on the outer circumferential surface of the transmission component 23. In the axial direction, at least a part of the first restricting portion 23b is located outside the left end part of the second hole 27. That is to say, during the left and right movement of the transmission component 23, the first restricting portion 23b may abut against the right end side wall of the housing 1 to prevent the transmission component 23 from falling off from the housing 1, and the second restricting portion 23c is snapped into a bar-shaped groove 1c provided in the second hole 27 to limit the rotation of the transmission component 23 during the movement process. That is to say, the second restricting portion 23c is provided on the transmission component 23, so that the transmission component 23 can only move axially, and the problem that the pushing portion 23a provided on the transmission component 23 cannot push the toggle member 22 due to the rotation of the transmission component 23 can be further avoided, thereby improving the pushing accuracy. The toggle member 22 may be arranged on the conductive side protective cover 29 in such a manner that it can slide relative to the conductive side protective cover 29. Preferably, a pair of sliding guide rails 26 are provided on the conductive side protective cover 29, and a pair of grooves 22a matching the sliding guide rails 26 are provided on the toggle member 22. The grooves 22a may be snapped into the pair of sliding guide rails 26 and can slide along the sliding guide rails 26 at least in an up and down direction. The toggle member 22 further includes a toggle portion 22b and a pushed portion 22c. The toggle portion 22b is used to contact the detection body in the image forming apparatus during the movement of the toggle member 22 and may toggle the detection body to move. When the transmission component 23 moves, the pushing portion 23a provided on the transmission component 23 pushes the pushed portion 22c to move the toggle member 22, wherein the number of pushed portions 22c is not limited, may be one or two or more, and may be specifically set according to the number of times for different developing cartridges that the toggle member 22 needs to toggle the detection body. The holding component 24 is arranged on the conductive side 20 of the developing cartridge. Preferably, a spring with a simple structure is used for the holding component 24. The holding component 24 is sleeved on the transmission component 23, one end thereof abuts against the right end side wall of the housing 1, and the other end abuts against the first restricting portion 23b of the transmission component 23. That is to say, the holding component 24 is limited between the housing 1 and the transmission component 23 to prevent it from falling off, and the holding component 24 may be used to urge the agitator shaft 7 to move close to the driving side 10. In other words, the holding force provided by the holding component 24 may keep the agitator shaft 7 stable in the first position, preventing the developing cartridge from forcing the agitator shaft 7 to leave the first position due to transportation or artificial external force, so that the transmission component 23 cannot push the toggle member and cause the toggle member to be unable to toggle the detection body of the image forming apparatus, resulting in the problem that the developing cartridge cannot be detected or fails to be detected. Further, sealing rings 25 are provided in the first hole 17 and the second hole 27 of the developing cartridge, respectively, and a pair of sealing rings 25 are sleeved on the left end of the agitator shaft 7 and the transmission component 23, respectively. The developing cartridge is provided with the sealing rings, which may be used to prevent the developer from leaking out from the developer accommodating portion 1a when the agitator shaft 7 and the transmission component 23 are moving.

Next, a process in which the developing cartridge is detected by the detection body of the image forming apparatus will be specifically described. First, when the coupling gear 4 does not receive the driving force in the image forming apparatus, the agitator shaft 7 is in the first position. At this time, the second transmission protrusion 8b of the agitator shaft 7 is not coupled with the coupling portion 6b of the agitator gear 6, and the first transmission protrusion 8a is engaged in the spiral groove 6a of the agitator gear 6. When the coupling gear 4 receives the driving force in the image forming apparatus and is driven to rotate, the coupling gear 4 transmits the driving force to the agitator gear 6 and drives the agitator gear 6 to rotate. However, since the second transmission protrusion 8b on the agitator shaft 7 is not coupled with the coupling portion 6b of the agitator gear 6 at this time, the agitator gear 6 in the rotation process generates a thrust force close to the right end in the axial direction only by means of the engagement of the spiral groove 6a and the first transmission protrusion 8a, so that the agitator shaft 7 can push the agitator shaft 7 to move from the left end to the right end against the elastic force of the holding component 24. At the same time, after the agitator shaft 7 starts to move, the agitator shaft 7 urges the transmission component 23 to move from the left end to the right end, that is, the transmission component 23 extends gradually to the right in the left and right direction. In the process of the transmission component 23 extending to the right, a pushing inclined surface 23a1 provided on the pushing portion 23a contacts and exerts force on the pushed inclined surface 22c1 on the pushed portion 22c, so that the toggle member 22 moves upward in the up and down direction. Optionally, since the transmission component 23 is provided with the pushing inclined surface 23a1, the pushed portion 22c on the toggle member 22 may not be provided with the pushed inclined surface 22c1, or only one of the two is provided with an inclined surface, which is not limited. It should be understood that the moving direction of the transmission component 23 does not need to completely overlap with the left and right direction. The transmission component 23 may move at an angle in the left and right direction, as long as its moving direction has a component in the left and right direction. In other words, the transmission component 23 only needs to move at least in the left and right direction. Similarly, the toggle member 22 also only needs to move at least in the up and down direction. In this embodiment, it is preferable that the transmission component 23 moves along the left and right direction, and the toggle member 22 moves along the up and down direction, so as to better describe the process of the developing cartridge being detected.

It should be noted that the toggle member 22 may toggle the detection body multiple times by being provided with a plurality of pushed portions 22c. The toggle member 22 may move back and forth in the up and down direction, and the detection body in the image forming apparatus itself has an elastic element for returning (not shown in the figure). When the toggle member 22 is required to toggle the detection body multiple times, each time the toggle member 22 toggles the detection body once, the detection body may return to a position where it can be toggled by the toggle member 22 again, that is, the detection body may move back and forth between a non-toggle position and a toggle position, so as to realize the detection of developing cartridges of different specifications. Moreover, the detection body in the image forming apparatus is further provided with a power supply component. The power supply component may supply power to the developer roller 2 and the developer feeding roller 9 in the developing cartridge, and in the process of the detection body being toggled to move, the inside of the image forming apparatus will identify whether the detection body is toggled by means of the electrical signal detection component connected to the power supply component.

Embodiment 2

Next, Embodiment 2 of the present disclosure will be introduced. Embodiment 2 shows a developing cartridge. For the same parts as the developing cartridge in Embodiment 1 described above, they will not be described in detail again in Embodiment 2. Embodiment 2 will focus on describing in detail the parts different from Embodiment 1 described above. The difference between Embodiment 2 and Embodiment 1 described above is that what pushes the transmission component to move may not be the agitator shaft, or it may be a separate rod to push the transmission component. The rod is different from the agitator shaft, that is, the force that pushes the transmission component to move may be generated by a rod that is different from the agitator shaft. Next, the solution in Embodiment 2 will be described in detail.

As shown in FIGS. 7-14, the agitator shaft 217 of this embodiment is configured so that it does not move left and right after receiving the driving force of the coupling gear 204, but it only rotates to agitate the developer in the housing 201. Therefore, to achieve the technical effect of pushing the toggle member 222 left and right, in this embodiment, the structure of the developing cartridge is changed and a new transmission structure is proposed. Specifically, the developing cartridge further includes a transmission component 223 arranged on the outer surface of the upper end of the housing 1. Of course, optionally, the transmission component 223 may also be arranged on the outer surface of the lower end of the housing 1 or inside the housing 1, which is not limited. The transmission component 223 is configured as a rod spanning the left and right ends of the housing 201. The transmission component 223 includes a first transmission part 223d and a first bending part 223c arranged at the left end, a second transmission part 223f and a second bending part 223e at the right end, and a middle connection part 223g of connecting the first bending part 223c and the second bending part 223e, wherein the first bending part 233c is connected between the first transmission part 223d and the middle connection part 223g, and separates the first transmission part 223d and the middle connection part 223g on different planes in the up and down direction. Specifically, in the up and down direction, the first transmission part 223d is located at the lower end of the middle connection part 223g. The second bending part 223e is connected between the second transmission part 223f and the middle connection part 223g, and separates the second transmission part 223f and the middle connection part 223g on different planes in the up and down direction. Specifically, in the up and down direction, the second transmission part 223f is located at the lower end of the middle connection part 223g. A first transmission protrusion 223a is formed on the outer surface of the first transmission part 223d. The first transmission protrusion 223a may be engaged with the spiral groove 206a on the agitator gear 206, so that when the agitator gear 206 receives the driving force of the coupling gear 204 to rotate, the axial force generated by the engagement of the first transmission protrusion 223a and the spiral groove 206a makes the agitator gear 206 push the transmission component 223 to move to the right during the rotation process. Therefore, the pushing portion 223b on the second transmission part 223f arranged at the right end can push the toggle member 222 to at least move upward, so that the toggle member 222 can toggle the detection body of the image forming apparatus to realize the detection function. The agitator gear 206 further includes a coupling portion 206b that may be coupled with the agitator shaft 207, and through the coupling of the two, the agitator gear 206 can drive the agitator shaft 207 to rotate. Further, the first transmission part 223d, the first bending part 223c, the second transmission part 223f, the second bending part 223e and the middle connection part 223g described above are integrally formed. Compared with a split transmission component, the integrally formed structure reduces the number of molds required for manufacturing the transmission component, thereby reducing the production cost. Moreover, the integrally formed structure makes it unnecessary to assemble the transmission component into a whole, thereby reducing the difficulty and time of assembling the developing cartridge, and improving the assembling efficiency. However, optionally, the first transmission part 223d, the first bending part 223c, the second transmission part 223f, the second bending part 223e, and the middle transmission part 223g may also be arranged separately, which is not limited. Only a preferred embodiment is used in this embodiment. Further, to prevent the middle transmission part 223g from being deformed when the transmission component 223 is forced to move to the right, a reinforcing rib may also be provided on the middle transmission part 223g or a limiting portion may be provided on a housing 201 outside the transmission component to avoid its deformation, so that the force can be stably transmitted. Further, in this embodiment, a holding component similar to that in the above embodiment may also be provided, so that the transmission component 223 in this embodiment can be stably held in the first position, preventing the developing cartridge from being forced to leave the first position due to transportation or artificial external force so that the transmission component 223 cannot push the toggle member 222, and thus the toggle member 222 cannot toggle the detection body of the image forming apparatus, resulting in the problem that the developing cartridge cannot be detected or fails to be detected.

Provided in this embodiment is a new transmission component which is different from the agitator shaft that can move left and right. The new transmission component is simple in structure and easy to assemble. Moreover, because the transmission component is arranged outside the housing, it also further reduces the developer leakage phenomenon that occurs during the movement of the transmission component. Further, because the transmission component is arranged outside the housing, it can reduce the resistance of the small transmission component in the process of moving left and right, further improving the stability of power transmission.

Embodiment 3

Next, Embodiment 3 of the present disclosure will be introduced. Embodiment 3 provides a new developing cartridge. For the same parts as those in the preceding embodiments, they will not be repeated in this embodiment. The difference is that the developing cartridge and the detection structure of the developing cartridge are changed. Next, the new detection structure will be described in detail.

As shown in FIGS. 15-27, the left end of the developing cartridge is further provided with a coupling gear 304 that can receive a driving force of an image forming apparatus, an agitator gear 306 engaged with an agitator, and a storage component (not shown) that can store information. However, the developing cartridge in this embodiment further includes a first transmission gear 337 connected between the coupling gear 304 and the agitator gear 306 and a second transmission gear 313 engagement with the agitator gear 306. That is to say, the second transmission gear 313 can receive the driving force of the coupling gear 304 transmitted through the first transmission gear 337 and the agitator gear 306 to rotate. The second transmission gear 313 has a first surface facing a housing 301 and a second surface opposite to the first surface without facing the housing 301. A driving portion 313b configured as a protrusion is formed on the second surface. The developing cartridge further includes a driven member 314 that is also arranged on the left end of the developing cartridge with the second transmission gear 313. The driven member 314 is arranged coaxially with the second transmission gear 313. The driven member 314 includes a pair of driven portions 314b which are also configured as protrusions. The pair of driven portions 314b are arranged at an interval on the outer peripheral surface of the driven member 314. Preferably, the two portions are arranged at an interval of 180 degrees in the rotational direction of the driven member 314. When the developing cartridge is a new cartridge, the driven member 314 is arranged such that one of the driven portions 314b abuts against the driving portion 313b of the second transmission gear 313. When the developing cartridge is mounted in the image forming apparatus and driven, the second transmission gear 313 is driven by the coupling gear 304 to rotate counterclockwise, so that the driving portion 313b of the second transmission gear 313 is out of contact with the driven portion 314b of the driven member 314 in the rotational direction and rotates between the pair of driven portions 314b. At this time, the driven member 314 still does not rotate and remains stationary until the driving portion 313b contacts the other driven portion 314b in the rotational direction. At this time, the driven member 314 is driven to start to rotate. The inner peripheral surface of the driven member 314 is further provided with a spiral groove 314a. The structure and function of the spiral groove 314a are similar to those of the spiral groove described in the above embodiments, and will not be repeated here.

Similarly, the transmission component 323 of the developing cartridge in this embodiment is supported by the housing 301 and at least partly arranged in the developer accommodating portion 1a of the housing 1. Optionally, the transmission component 323 may also be arranged outside the housing 301, and the transmission component 323 is configured to span the left and right ends of the housing 1. As in the previous embodiments, the left end portion of the transmission component 323 is further provided with a first transmission protrusion 323a that can be engaged with the spiral groove 314a of the driven member 314. Similar to the previous embodiments, when the developing cartridge is a new cartridge and the second transmission gear 313 drives the driven member 314 to start rotating, the spiral groove 314a is engaged with the first transmission protrusion 323a to generate a thrust force forcing the transmission component 323 to move rightward, that is to say, the rotation of the driven member 314 can force the second transmission component 323 to move to the right. Of course, the structure for transforming the rotational motion into the translational motion is not limited to the matching structure between the spiral groove 314a and the first transmission protrusion 323a used in this embodiment and the above embodiments, and a structure in which a worm screw and a rack cooperate or other structures, for example, may also be used, but a preferred transmission structure is used in the present disclosure. The left end of the transmission component 323 is further provided with a blocking portion 323h. The blocking portion 323h is configured as an annular protrusion extending radially outward from the outer surface of the transmission component 323. The blocking portion 323h is arranged adjacent to the first transmission protrusion 323a, and is arranged in a position closer to the center of the transmission component 323 relative to the first transmission protrusion 323a in the left and right direction. A holding component 315 is also provided between the left end side wall of the housing 301 and the blocking portion 323h. Further, the holding component 315 is preferably a compression spring with simple structure and low cost. When the developing cartridge is a new cartridge, the holding component 315 is arranged between the left end side wall of the housing 301 and the blocking portion 323h in a compressed manner. As the transmission component 323 moves to the right, the compression amount of the holding component 315 gradually decrease until the first transmission protrusion 323a of the transmission component 323 is disengaged from the spiral groove 314a of the driven member 314. At the moment when the two are disengaged, the elastic force accumulated in the holding component 315 in the compressed state is released, urging the transmission component 323 to accelerate to move to the right. However, the first transmission protrusion 323a detached from the spiral groove 314a will cause the left end part of the transmission component 323 to lose support. Further, referring to FIG. 23, to avoid the occurrence of this situation, a supporting portion 301d is further provided on the housing 301. The supporting portion 301d is a hollow pipe extending rightward from the left end side wall of the housing 301. The left end part of the transmission component 323 is accommodated in the supporting portion 301d. When the first transmission protrusion 323a is disengaged from the spiral groove 314a, the left end part of the transmission component 323 will be supported by the supporting portion 301d, so that the left end part of the second transmission component 323 will not become unstable due to the loss of support.

At least one pushing portion 323b is provided at the right end of the transmission component 323. The specific number of pushing portions 323b and the interval between adjacent pushing portions 323b may be set according to the specifications of different developing cartridges, which is not limited. The developing cartridge in this embodiment is provided with four pushing portions 323b for illustration. The four pushing portions 323b are arranged at intervals in the left and right direction, and the pushing portions 323b are accommodated in a pushing portion accommodating portion 301b arranged on the upper end of the right side of the housing 301, so that the pushing portion 323b is not provided in the developer accommodating portion 301a and is exposed outside. With this structure, it is possible to avoid the phenomenon that the movable and complex-shaped pushing portion 323b is provided in the developer accommodating portion 301a, making the developer accommodating part 301a not well sealed and resulting in developer leakage. A plurality of pushing portions 323b may push the pushed portion 322c of the toggle member 322 to make the toggle member 322 (interchangeably referred to as “toggle protrusion” or “first protrusion”) move back and forth, so that the toggle member 322 toggles the detection body of the image forming apparatus back and forth several times to make the developing cartridge detected. Further, similar to Embodiment 1 or 2 described above, the pushing portion 323b is provided with a pushing inclined surface, and the pushed portion 322c is provided with a pushed inclined surface. When the pushing portion 323b pushes the pushed portion 322c, the inclined surfaces are pushed to contact each other, so as to make it easier for the transmission component 323 to push the toggle member 322, and the movement is smoother. Optionally, only one of the pushing portion 323b and the pushed portion 322c may be provided with an inclined surface, and the same technical effect may also be achieved. Moreover, it should be understood that the moving direction of the transmission component 323 does not need to completely overlap with the left and right direction, and the transmission component 323 may move along a direction at an angle with the left and right direction, as long as its moving direction has a component in the left and right direction, in other words, the transmission component 323 moves at least in the left and right direction. In this embodiment, it is preferable that the transmission component 323 moves along the left and right direction so as to better describe the detection process of the developing cartridge. To realize that the toggle 322 stably toggles the detection body of the image forming apparatus back and forth, the toggle member 322 is further provided with a sliding portion 322d, and the right end side wall of the housing 301 is provided with a track portion 301c for the sliding portion 322d to slide. When the toggle member 322 is toggled by force, the sliding portion 322d may slide along a predetermined track provided by the track portion 301c. Further, the sliding portion 322d is configured as an elastic buckle. It not only enables the sliding portion 322d to slide stably on the track portion 301c, but also enables the toggle member 322 to be detachably mounted on the housing 301 through the elastic buckle structure while preventing it from accidentally falling off from the housing 301, so that the structure of the toggle member is simplified, and the installation or removal of the toggle member 322 becomes simpler and more convenient. Further, the developing cartridge also includes a first elastic member 324. The first elastic member 324 is connected between the housing 301 and the toggle member 322, and is used to reset the toggle member 322 after the toggle member 322 is pushed by the transmission component 323, so that the toggle member 322 can toggle the detection body of the image forming apparatus back and forth. Further, the first elastic member 324 is preferably a tension spring.

Next, a process in which the developing cartridge is detected by the detection body of the image forming apparatus will be specifically described. First, as a new developing cartridge, when the coupling gear 304 does not receive the driving force in the image forming apparatus, one of the driven portions 314b of the driven member 314 abuts against the driving portion 313b of the second transmission gear 313. When the developing cartridge is mounted in the image forming apparatus and driven, the second transmission gear 313 is driven by the coupling gear 304 to rotate counterclockwise, so that the driving portion 313b of the second transmission gear 313 is out of contact with the driven portions 314b of the driven member 314 in the rotational direction and rotates between the pair of driven portions 314b. At this time, the driven member 314 still does not rotate until the driving portion 313b contacts the other driven portion 314b in the rotational direction. At this time, the driven member 314 is driven to start rotating. Subsequently, the driven member 314 which starts rotating can generate a rightward thrust force by means of the engagement of the spiral groove 314a provided thereon and the first transmission protrusion 323a of the transmission component 323. The thrust force causes the transmission component 323 to be pushed rightward by the driven member 314. As the transmission component 323 moves to the right, the pushing portion 323b arranged at the right end of the transmission component 323 starts to push the pushed portion 322c of the toggle member 322. The toggle member 322 moves the sliding portion 322d on the track portion 301c against the elastic force of the first elastic member 324, so that the toggle member 322 moves from the position shown in FIG. 25 in which the detection body of the image forming apparatus is not pushed to a position in which the detection body of the image forming apparatus is pushed. At this time, the detection body that is toggled by the toggle member 322 records a toggle signal. Further, as shown in FIG. 27, the pushed portion 322c of the toggle member 322 will be out of contact with the pushing portion 323b, so that the toggle member 322 moves to a groove formed by two adjacent pushing portions 323b under the elastic force of the first elastic member 324. At this time, the toggle member 322 again returns to the position where the detection body of the image forming apparatus is not toggled. Similarly, the cooperation process of the three subsequent pushing portions 323b and the toggle member 322 is similar to that of the first pushing portion 323b and the toggle member 322, and will not be repeated here. It is worth mentioning that as the transmission component 323 gradually moves to the right, the compression amount of the holding component 315 will gradually decrease until the first transmission protrusion 323a of the transmission component 323 is about to be disengaged from the spiral groove 314a of the driven member 314. At the moment when the two are disengaged, the elastic force accumulated in the holding component 315 that is still in the compressed state is released, and the elastic force is applied to the transmission component 323 and can urge the transmission component 323 to acceleratingly move to the right, so that the pushing portion 323b accelerates to push the toggle member 322, and then the toggle member 322 accelerates to toggle the detection body of the image forming apparatus. The detection body can receive the accelerated toggle signal. Finally, the first transmission protrusion 323a is disengaged from the spiral groove 314a, the transmission component 323 will no longer move to the right, and the toggle member 322 will no longer move and will no longer toggle the detection body of the image forming apparatus. So far, the image forming apparatus has completed the entire detection process of the developing cartridge.

Embodiment 4

Next, Embodiment 4 in the present disclosure will be introduced. A developing cartridge is shown in Embodiment 4, and the same parts of the developing cartridge as the developing cartridge in Embodiment 3 described above will not be repeated. The difference is that the detection structure of the developing cartridge is changed in this embodiment. Next, the new detection structure will be described in detail.

As shown in FIGS. 39-53, first, the partial structure of the left end of the developing cartridge will be described. The left end of the developing cartridge is further provided with a coupling gear 504 that can receive the driving force of the image forming apparatus, a developer roller gear 505, a developer feeding roller gear 538, a first transmission gear 537, an agitator gear 506 and a second transmission gear 513 that can be driven by the coupling gear 504, and a driving side protective cover 519 covering the above gears, wherein the driving side protective cover 519 is provided with a protruding column 519a on a side toward a housing 501. An abutted protrusion 519a1 is provided at a free end of the protruding column 519a. The protruding column 519a and the abutted protrusion 519a1 are configured as a buckle structure formed on the driving side protective cover 519. The buckle structure can be abutted against and buckled on the driven member 514 to prevent the driven member 514 and the second transmission gear 513 from falling off from the driving side protective cover 519. Similarly, the second transmission gear 513 may receive a driving force of the coupling gear 504 transmitted through the first transmission gear 537 and the agitator gear 506 to rotate. The second transmission gear 513 has a first surface facing the housing 501 and a second surface opposite to the first surface and not facing the housing 501. A driving portion 513b configured as a protrusion is formed on the first surface.

The developing cartridge further includes a driven member 514 which is also arranged on the left end of the developing cartridge with the second transmission gear 513, and a transmission member 523 which can be urged to move by the driven member 514 and spans the left and right ends of the housing 501. Further, the driven member 514 is arranged coaxially with the second transmission gear 513, which makes the structure of the developing cartridge more compact and facilitates the miniaturization of the developing cartridge. Unlike the driven member in the above embodiments, the driven member 514 in this embodiment has a basic structure similar to that of a toothed disc. The driven member 514 includes a driven member main body portion 565 configured in a disc shape, and a pair of driven portions 514b protruding from the driven member main body portion 565 toward the second transmission gear 513 side in the left and right direction. The pair of driven portions 514b are configured as protrusions, and the pair of driven portions 514b are arranged at an interval in the rotational direction of the driven member main body portion 565. Preferably, the pair of driven portions 514b are arranged at an interval of 180 degree on the rotational direction of the driven member main body portion 565. When the developing cartridge is a new cartridge, the driven member 514 is arranged such that one of the driven portions 514b abuts against the driving portion 513b of the second transmission gear 513. When the developing cartridge is mounted in an image forming apparatus and driven, the second transmission gear 513 is driven by the coupling gear 504 to rotate counterclockwise, so that the driving portion 513b of the second transmission gear 513 is out of contact with the driven portion 514b of the driven member 514 in the rotational direction and rotated between the pair of driven portions 514b. At this time, the driven member 514 still does not rotate and remains stationary until the driving portion 513b contacts the other driven portion 514b in the rotational direction. At this time, the driven member 514 is driven to start rotating. That is to say, such a configuration makes the driven member 514 remain stationary when the coupling gear 504 is just driven to rotate. The driven member 514 will start rotating after the coupling gear 504 rotates for a period of time. In other words, the developing cartridge has the function of delay detection. Such a structure is similar to that in Embodiment 3 described above, so it will not be repeated here. The driven member 514 further includes an urging portion protruding from the driven member main body portion 565 toward the housing 501 side in the left and right direction. The urging portion is configured as a protrusion (interchangeably referred to as “second protrusion” or “urging protrusion”), and there is at least one urging portion. Further, there are four urging portions in this embodiment, namely, a first urging portion 561, a second urging portion 562, a third urging portion 563 and a fourth urging portion 564 arranged at intervals in the rotational direction of the driven member main body portion 565. Optionally, 1-3 or 4 or more urging portions are may also be provided. The urging portions may be specifically provided according to the model specifications of the developing cartridge. Further, the second urging portion 562 includes an urging surface 562b and a guide surface 562a adjacent to the urging surface 562b, and, in the rotational direction of the driven member 514, the urging surface 562b is arranged upstream of the guide surface 562a. The urging surface 562b is located on a different plane from the surface of the driven member main body portion 565 facing the housing 501 side, and is closer to the right end of the developing cartridge relative to the driven member main body portion 565 in the left and right direction. One end of the guide surface 562a is adjacent to the driven member main body portion 565, and the other end is adjacent to the urging surface 562b. In other words, the guide surface 562a is inclined from the driven member main body portion 565 toward the urging surface 562b, and the guide surface 562a may be used to guide the urged portion 523a located at the left end of the transmission component 523 to move to the urging surface 562b. In other words, when the driven member 514 rotates, the guide surface 562a can smoothly push the transmission component 523 to move from left to right. The structures and functions of the third urging portion 563 and the fourth urging portion 564 are the same as those of the second urging portion 562, which will not be repeated here. Further, the driven member 514 also includes an abutting portion 560 protruding from the driven member main body portion 565 toward the housing 501 side. Viewed from the right end to the left end, the shape of the abutting portion 560 has a basic structure of a cam. The abutting portion 560 includes an abutting surface 560a and an abutting groove 560b. A plane where the abutting surface 560a is located is closer to the right end of the developing cartridge in the left and right direction than the first surface of the driven member main body portion 565 facing the housing 501 side, and the abutting groove 560b is formed by inwardly recessing from the abutting surface 560a. When the developing cartridge is a new cartridge or the developing cartridge is in the process of detection, the abutted protrusion 519a1 of the driving side protective cover 519 abuts against the abutting surface 560a. At this time, the driving portion 513b of the second transmission gear 513 abuts against the driven portion 514b of the driven member 514 and can drive the driven member 514 to rotate. When the detection is completed, the abutted protrusion 519a1 is out of contact with the abutting surface 560a and abuts against the abutment groove 560b. At this time, the driving portion 513b of the second transmission gear 513 is axially disengaged from the driven portion 514b of the driven member 514, so that the driven member 514 cannot be driven to rotate. That is to say, after the detection of the developing cartridge is completed, the driven member 514 cannot be driven, and then the driven member 514 will not push the transmission member 523 to move in the left and right direction.

Further, the developing cartridge also includes a second elastic member 553. The second elastic member 553 is preferably a torsion spring, and includes a main body part and a first extension portion and a second extension portion respectively extending from the left and right ends of the main body part. The main body part of the second elastic member 553 is sleeved on a positioning column 501m on the left end wall of the housing 501. The first extension portion is mounted in a positioning slot 501n also located on the left end wall of the housing 501 to be positioned, and the second extension portion leans against the outer surface of the abutting portion 560 configured as a cam. During the rotation of the driven member 514, the second elastic member 553 may be twisted to accumulate elastic force. After the urged portion 523a of the transmission component 523 is out of contact with the third pushing portion 563 of the driven member 514, the elastic force accumulated by the twisting of the second elastic portion 553 is released, and the elastic force acts on the abutting portion 560 and may force the driven member 514 to acceleratingly rotate.

Further, to make it easier for the abutted protrusion 519a1 that is out of contact with the abutting surface 560a to enter the abutting groove 560b stably and quickly after the detection of the developing cartridge is completed, the developing cartridge is further provided with a third elastic member 551. The elastic member 551 abuts between the driven member 514 and the second transmission gear 513, and when the abutted protrusion 519a1 abuts on the abutting surface 560a, the third elastic member 551 is in a compressed state and accumulates an elastic force. The elastic force has a tendency to urge the driven member 514 to move toward the right end. When the abutted protrusion 519a1 is out of contact with the abutting surface 560a and faces the abutting groove 560b, the accumulated elastic force is released to urge the driven member 514 to move to the right end. At this time, the abutted protrusion 519a1 enters the abutment groove 560b on the moved driven member 514. Thus, the driven portion 514b of the driven member 514 is axially disengaged from the driving portion 513b of the second transmission gear 513. Further, the third elastic member 551 is a compression spring, which has a simple structure and stable performance.

Further, during the detection process of the developing cartridge, it is necessary to toggle the detection body of the image forming apparatus several times to complete the detection. To this end, the developing cartridge is further provided with a holding component 531. The holding component 531 is mounted in the approximately central position of the housing 501 in the left and right direction, the holding component 531 abuts between the transmission component 523 and the housing 501, and may be used to reset the moved transmission component 523, Specifically, when the developing cartridge is a new cartridge, the urged portion 523a of the transmission component 523 abuts against the first urging portion 561 of the driven member 514 against the elastic force accumulated in the holding component 531. At this time, the transmission component 523 tends to move leftward (that is, it is close to the driven member 514 side in the left and right direction) due to the elastic force of the holding component 531, and the transmission component 523 in this position is in a position where the detection body of the image forming apparatus may be toggled by the toggle member 522. With the rotation of the driven member 514, the urged portion 523a is gradually out of contact with the first urging portion 561, and the transmission component 523 will move to the left under the action of the elastic force of the holding component 531 until it abuts against the driven member main body portion 565 and stops moving. The transmission component 523 in this position is in a position where the detection body of the image forming apparatus is not toggled. That is to say, the holding component 531 has a tendency to force the transmission component 523 to move from the position where the detection body of the image forming apparatus is toggled to the position where the detection body of the image forming apparatus is not toggled, so as to reset the transmission component 523 after it moves.

As shown in FIGS. 51-53, similar to Embodiment 3 described above, the right end of the developing cartridge in this embodiment likewise includes a movable toggle member 522 and a first elastic member 524 abutting between the toggle member 522 and the housing 501. The toggle member 522 includes a toggle portion 522b that can toggle the detection body of the image forming apparatus and a pushed portion 522c that can be pushed by the pushing portion 523b of the transmission component 523. Moreover, after receiving the pushing force of the pushing portion 523b, the toggle member 522 can slide along the track portion 501c provided on the housing 501, and the elastic force generated by the first elastic member 524 can be used to keep the toggle member 522 in a non-toggle position where the detection body of the image forming apparatus is not toggled. When the toggle member 522 is pushed to move by the pushing portion 523b of the transmission component 523 moving to the right, the toggle member 522 moves, against the elastic force generated by the compression of the first elastic member 524, to a toggle position where the detection body of the image forming apparatus may be toggled. When the transmission component 523 moves to the left, the pushing portion 523b will no longer push the toggle member 522. At this time, the toggle member 522 returns to the non-toggle position again under the action of the elastic force accumulated on the first elastic member 524. That is to say, the first elastic member 524 may be used to reset the toggling member 522 from the toggle position to the non-toggle position. Further, the pushing portion 523b is provided with a pushing inclined surface to smoothly push the toggle member 522. Optionally, it is also possible that the pushing portion 523b and the pushed portion 522c is each provided with an inclined surface, or only the pushed portion 522c is provided with an inclined surface, all of which can achieve the above technical effects.

As shown in FIGS. 39-53, next, the process in which the developing cartridge is detected by the detection body of the image forming apparatus will be described in detail. First, as shown in FIG. 46, as a new developing cartridge, the urged portion 523a of the transmission member 523 abuts against the first urging portion 561 to keep the transmission component 523 in a pushing position where the pushing portion 523b pushes the pushed portion 522c of the toggle member 522, and the abutted protrusion 519a1 of the driving side protective cover 519 is abutted on the abutting surface 560a. After the user mounts the new developing cartridge into the image forming apparatus, the toggle member 522 is in a toggle position where the detection body of the image forming apparatus is toggled. With the start of the image forming apparatus, the coupling gear 504 is driven to rotate. Through the power transmission of the first transmission gear 537 and the agitator gear 506, the second transmission gear 513 is also driven to rotate in the counterclockwise direction, but the driving portion 513b of the subsequent second transmission gear 513 will rotate between the pair of driven portions 514b of the driven member 514 and will not drive the driven member 514 to rotate temporarily. With the further rotation of the second transmission gear 513, the driving portion 513b abuts against the other driven portion 514b and drives the driven member 514 to start rotating. That is to say, when the second transmission gear 513 starts rotating, the driven member 514 will not rotate immediately, but will start rotating after a period of time, with a certain delay. As shown in FIG. 47, With the rotation of the driven member 514, the urged portion 523a abutting against the first urging portion 561 is out of contact with the first urging portion 561, and the urged portion 523a is urged to move to the left under the elastic force of the holding component 531 until it abuts against the driven member main body portion 565 and stops continuing to move forward. With the further rotation of the driven member 514, as shown in FIG. 48, the urged portion 523a abuts against the guide surface 562a of the second urging portion 562, and under the guidance of the guide surface 562a, the transmission component 523 gradually moves to the right. The pushing portion 523b located at the right end of the transmission component 523 will push the toggle member 522 to move against the elastic force of the first elastic member 524, and then the toggle member 522 will push the detection body of the image forming apparatus. The image forming apparatus will detect the toggle signal. Further, as shown in FIG. 49, when the urged portion 523a is out of contact with the guide surface 562a and moves to contact with the urging surface 562b, the transmission component 523 will temporarily no longer move to the right. At this time, the pushing portion 523b will maintain the state of pushing the toggle member 522 and force the toggle member 522 to continue to toggle the detection body of the image forming apparatus. The image forming apparatus will detect and record the duration of the toggle signal again. However, with the further rotation of the driven member 514, the urged portion 523a is out of contact with the urging surface 562b, and is urged to move to the left under the elastic force of the holding component 531 until it abuts against the driven member main body portion 565 again. Next, the cooperating process between the urged portion 523a and the third urging portion 563 is similar to the cooperating process between the urged portion 523a and the second urging portion 562, and the transmission component 523 will repeat the previous action process, which will not be repeated here. With the further rotation of the driven member 514, the second elastic member 553 is twisted to accumulate an elastic force. Then, the elastic force is released and applied to the abutting portion 560 to accelerate the rotation of the driven member 514. Then, the urged portion 523a abuts against the fourth urging portion 564 and abuts on the urging surface of the fourth urging portion 564. At this time, the abutted protrusion 519a1 of the driving side protective cover 519 is out of contact with the abutting surface 560a, and the elastic force accumulated by the third elastic member 551 is released to urge the driven member 514, so that the abutted protrusion 519a1 enters the abutting groove 560b on the driven member 514, thereby urging the driven member 514 to move toward the right end. At this time, the driven portion 514b of the driven member 514 is axially disengaged from the driving portion 513b of the second transmission gear 513. So far, the driven member 514 can no longer receive the driving force from the second transmission gear 513 to rotate, so that the transmission component 523 will not move left and right. At this time, the transmission component 523 will again remain at a pushing position where the pushing portion 523b pushes the pushed portion 522c of the toggle member 522, and the toggle member 522 continues to abut against the detection body of the image forming apparatus. The image forming apparatus will receive the toggle signal again, and the detection process is terminated.

Beneficial Effects

After adopting the above technical solutions, a new developing cartridge detected assembly is provided, which adopts a spiral groove structure design or a gear disc structure design to transmit the driving force, so that the transmission component can move in the left and right direction. Compared with the existing gear transmission structure, this structure design has a smaller space. Therefore, the developing cartridge can be made thinner and smaller.

The above embodiments are only used to illustrate the technical solutions of the present disclosure, rather than to limit them. Although the present disclosure has been described in detail with reference to the foregoing embodiments, it should be understood by those of ordinary skill in the art that: it is still possible to modify the technical solutions described in the foregoing embodiments, or to perform equivalent replacements for some of the technical features. These modifications or replacements do not make the essence of the corresponding technical solutions deviate from the spirit and scope of the technical solutions in the embodiments of the present disclosure.

Number	Date	Country	Kind
202123186229.3	Dec 2021	CN	national
202123284036.1	Dec 2021	CN	national
202123353961.5	Dec 2021	CN	national
202220461237.X	Mar 2022	CN	national

	Number	Date	Country
Parent	PCT/CN2022/138241	Dec 2022	US
Child	18236433		US

DEVELOPING CARTRIDGE

Information

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CPC

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Abstract

Description

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Priority Claims (4)

Continuations (1)