CN106353993B - Processing box - Google Patents

Abstract

The present invention relates to a process cartridge detachably mountable to an electrophotographic image forming apparatus, including a process cartridge housing and a photosensitive member mounted in the housing, the photosensitive member having a rotational axis L1, including a photosensitive drum, and a power transmitting device connected to the photosensitive drum, the power transmitting device including a force applying mechanism and a power receiving mechanism cooperating with each other, the power receiving mechanism being extended and retracted along the rotational axis L1 by the force applying mechanism, the force applying mechanism applying different forces to the power receiving mechanism at different time periods during one cycle of extension and retraction of the power receiving mechanism, when the power receiving member in the power receiving mechanism is connected to the photosensitive drum through a flange cylinder and transmits power, it is not necessary to provide a barb portion on a projection of the flange cylinder at a position close to an opening of the flange cylinder, and it is not necessary to precisely control a distance between the barb portions, therefore, the manufacturing accuracy of the power transmission device in the process cartridge is not required to be high.

Description

Processing box

Technical Field

The present invention relates to the field of electrophotographic image forming, and more particularly, to a process cartridge detachably mountable in an electrophotographic image forming apparatus.

Background

The electrophotographic imaging is a process of charging and exposing a photosensitive member by utilizing the photosensitivity of the photosensitive member, and then sequentially performing development, transfer printing, fixing and cleaning; a process cartridge is a consumable in an electrophotographic image forming process, and includes a plurality of rotary members, in addition to the above-described photosensitive member having a cylindrical shape, a member for charging the same, such as a charging roller having a cylindrical shape, and a member for performing development, such as a developing roller having a cylindrical shape or a magnetic roller, which are constantly rotated during the electrophotographic image forming process, and therefore, the rotary members must be supplied with rotational power during the electrophotographic image forming process.

If the photosensitive member is mounted in the process cartridge, generally, power is supplied by the electrophotographic image forming apparatus, a power receiving device is provided at one end of the photosensitive member, the device receives a driving force from the electrophotographic image forming apparatus to rotate the photosensitive member, and the photosensitive member transmits the driving force to the charging roller, the developing roller, or the magnetic roller; if the photosensitive member is mounted in an electrophotographic image forming apparatus, a power receiving device is provided at one end of the developing roller or the magnet roller.

Fig. 1 is a schematic view showing an overall structure of a conventional photosensitive member, wherein the photosensitive member 020 has a rotation axis L01, and includes a photosensitive drum 22 having a surface coated with a photosensitive material, and a power transmission device 021 disposed at one longitudinal end of the photosensitive drum, the power transmission device including a flange cylinder 0210, a gear 02106 disposed at an outer periphery of the flange cylinder, and a power receiving member 0212 engaged with the flange cylinder and transmitting a driving force to the flange cylinder, the power receiving member having a rotation axis L02 and transmitting the received driving force to the photosensitive drum through the flange cylinder, so that the photosensitive member rotates.

Fig. 2 is a schematic view of an overall structure of a power receiving element in a conventional photosensitive element, the power receiving element 0212 includes a first part 0212a for receiving a driving force from the outside, a second part 0212b, a third part 0212c for transmitting the driving force, and a pin 0212d, the third part 0212c is spherical so that the power receiving element 0212 can freely swing, and the second part 0212b for connecting the first part and the third part.

Fig. 3 is a sectional view of a flanged cylinder in a conventional photosensitive member, the flanged cylinder 0210 includes a flanged cavity 02100 surrounded by a cylinder body, and a protrusion 02105 protruding radially inward from the inner wall of the cylinder body, the flanged cavity 02100 serves to receive a spherical third portion 0212c of a power receiving member, and a pin 0212d in the power receiving member is engaged with the protrusion 02105, so that the pin can always transmit a driving force to the flanged cylinder regardless of whether rotation axes L02 and L01 are coaxial.

For ease of installation, the third portion of the power receiver 0212c is typically pressed directly into the flanged cavity 02100 from the opening of the flanged cylinder. In the prior art, in order to prevent the power receiving part 0212, which is spherical in shape, from coming out of the flanged cylinder 0210, as shown in fig. 3, a barb 02107 is provided on the projecting part 02105 near the opening of the flanged cylinder, and the distance between the opposing barbs is smaller than the diameter of the third part 0212c in the radial direction of the flanged cylinder, however, if the distance is too small, although the falling-out of the power receiving part is effectively prevented, it will cause the third part 0212c of the power receiving part not to be easily pressed into the flanged cavity; if the distance is too large, the falling-off of the power receiving member cannot be effectively prevented, and therefore, the distance, i.e., the size of the barb 02107 must be precisely controlled.

Disclosure of Invention

In view of the above, the present invention provides a processing box, which has low requirement on the overall manufacturing precision of the power transmission device on the premise of ensuring that the power receiving part does not fall off.

In order to achieve the purpose, the invention adopts the following technical scheme:

a process cartridge detachably mountable to an electrophotographic image forming apparatus having a power take-off, the process cartridge including a process cartridge housing and a photosensitive member mounted in the housing, the photosensitive member having a rotation axis L1, including a photosensitive drum and a power transmitting device connected to the photosensitive drum, the power transmitting device including a force applying mechanism and a power receiving mechanism cooperating with each other, the power receiving mechanism being extended and retracted along the rotation axis L1 under the action of the force applying mechanism, the force applying mechanism applying different forces to the power receiving mechanism at different time periods in one cycle of the extension and retraction of the power receiving mechanism.

Wherein, the one cycle comprises a first time period t1, a second time period t2 and a third time period t3, the third time period t3 is located between the first time period t1 and the second time period t2, when the force application mechanism applies force to the power receiving mechanism, the action processes are as follows: a first time period t1, a third time period t3, and a second time period t 2.

In a first time period, the force application mechanism applies thrust to the power receiving mechanism; in a second time period, the force application mechanism applies pulling force to the power receiving mechanism; in the third time period, the force applying mechanism does not apply any force to the power receiving mechanism.

The first time period t1 is the time period from the time when the force application mechanism is started to the time when the power receiving mechanism is combined with the power output piece; the second time period t2 is the time period from when the force application mechanism is activated again until the power receiving mechanism is pulled back out of engagement with the power take-off; the third time period t3 is a time period from when the photosensitive member starts to rotate to when the urging mechanism is activated again.

Preferably, the first time period t1 satisfies: 2s < t1 < 3s, and a second time period t2 satisfies: 2s < t2 < 3 s.

More preferably, the first time period t1 and the second time period t2 further satisfy: t1 ═ t 2.

As described above, in one cycle of the extension and retraction of the power receiving mechanism, the force applying mechanism applies different acting forces to the power receiving mechanism at different time periods, and when the power receiving element in the power receiving mechanism is connected with the photosensitive drum through the flange cylinder and transmits power, the power receiving element can be effectively prevented from falling off without arranging the barb part on the protruding part of the flange cylinder at a position close to the opening of the flange cylinder; since there is no need to precisely control the distance between the barb portions, the manufacturing accuracy of the power transmission device in the process cartridge is not so high.

Drawings

Fig. 1 is a schematic view of the overall structure of a conventional photosensitive member.

Fig. 2 is a schematic view of the overall structure of a power receiving member in a conventional photosensitive member.

Fig. 3 is a sectional view of a flanged cylinder in a conventional photosensitive member.

FIG. 4 is a schematic view showing a structure of a process cartridge according to the present invention

FIG. 5 is a schematic view of a photosensitive member according to the present invention

Fig. 6A is a partially exploded schematic view of a power transmission device according to an embodiment of the present invention.

Fig. 6B is an exploded view of a part of the power transmission device according to the second embodiment of the present invention.

Fig. 6C is an exploded view of a part of the third embodiment of the power transmission device of the present invention.

Fig. 7 is a sectional view of the power transmission device a-a in fig. 6C.

Fig. 8 is an exploded view of a part of a fourth embodiment of the power transmission device of the present invention.

Fig. 9A to 9C are schematic views showing a process of coupling the power receiving mechanism and the power output member according to the present invention.

Fig. 10A to 10C are schematic views showing a process of disengaging the power receiving mechanism and the power output member according to the present invention.

Fig. 11 is an exploded view of an electrical contact portion of a photosensitive member in the present invention.

Fig. 12 is a schematic view showing the connection of the electric contact portion of the photosensitive member to an external circuit in the present invention.

Fig. 13 is a block diagram of a first embodiment of a power supply control circuit.

Fig. 14 is a block diagram of a second embodiment of the power supply control circuit.

Fig. 15A is a schematic view of a state in which the power transmission device is in a blind spot position when the machine is installed.

Fig. 15B is a schematic view of a state in which the power transmission device is in a blind spot position while offline.

FIG. 16 is a block diagram of the circuitry used by the present invention to address dead-corner locations.

FIGS. 17A-17C are schematic views of a process for solving dead space of the installation.

FIGS. 18A-18C are schematic views of a process for solving offline deadspace.

Detailed Description

As described above, the process cartridge may include a plurality of rotary members such as a photosensitive member, a charging roller, a developing roller, etc., and hereinafter, the photosensitive member will be described in detail as an example for clarity in describing embodiments of the present invention.

Fig. 4 is a schematic structural view of a process cartridge according to the present invention, the process cartridge C including a process cartridge housing 1, and a photosensitive member 20 and a holder 24 mounted in the housing; fig. 5 is a schematic structural diagram of a photosensitive member according to the present invention, wherein the photosensitive member 20 has a rotation axis L1, and the direction of the rotation axis L1 is set as a longitudinal direction, as shown in the figure, the photosensitive member 20 includes a photosensitive drum 22, and a power transmission device 21 and an electrical contact 23 respectively connected to the photosensitive drum, and the power transmission device 21 has a rotation axis L2, in an embodiment of the present invention, the rotation axis L2 of the power transmission device and the rotation axis L1 of the photosensitive drum are always coaxial; as shown in fig. 4, the power transmission device 21 is coupled to the power output member 3 and receives power from the power output member 3.

[ Structure of Power Transmission device ]

Example one

Fig. 6A is a partially exploded schematic view of the power transmission device according to the present embodiment. The power transmission device 21 includes a force application mechanism 211 and a power receiving mechanism, which are mutually matched, preferably, the power receiving mechanism is located at one longitudinal end of the photosensitive drum 22, and the force application mechanism 211 is located inside the photosensitive drum 22. In the present embodiment, the power receiving mechanism is the power receiving member 212, and the power receiving member 212 is extended and retracted along the rotational axis L2 of the power transmission device (rotational axis L1 of the photosensitive member) by the urging mechanism 211. As shown, the power receiving element 212 includes a first portion 212a, a second portion 212b, and a third portion 212 c; the first portion 212a is used to receive power from the outside, the third portion 212c is used to transmit power to the photosensitive member, and in this embodiment, the third portion 212c is directly engaged with the photosensitive member, and the second portion 212b is used to connect the first portion and the third portion. As shown in fig. 6A, the rotation axis of the power transmission device 21 is L2, the power receiving element 212 has a rotation axis L3, in the embodiment of the present invention, the rotation axis L2 is coaxial with the rotation axis L3, that is, the power receiving element 212 is always coaxial with the photosensitive element, and the power receiving element 212 moves along the rotation axis L2 of the power transmission device 21 by receiving the pushing or pulling force from the forcing mechanism 211.

The first portion 212a of the power receiving member is located at one end of the second portion 212b and includes a circular disk 212a1 and at least one pair of power receiving portions 212a2, preferably a pair, disposed diametrically opposite each other along the disk, while a power receiving face 212a21 is also provided on each power receiving portion 212a2, as shown, the power receiving face is planar and parallel to the rotational axis L3 of the power receiving member 212; the second part 212b of the power receiving part is a cylindrical body, and the disc 212a1 is fixedly connected with one end of the cylindrical body; the third portion 212c of the power receiving member includes at least one pair of power transmission members 212c2 disposed opposite to each other in the radial direction of the cylindrical body, preferably, the pair of power transmission members, which in this embodiment directly cooperate with the photosensitive drum 22 to transmit the power received by the first portion 212a to the photosensitive drum.

As described above, the power receiving element 212 needs to receive the pushing force or pulling force from the force applying mechanism 211, and for this purpose, in the embodiment of the present invention, the power receiving element 212 and the force applying mechanism 211 are in threaded engagement, that is, an internal thread or an external thread is provided on the power receiving element 212, and correspondingly, an external thread or an internal thread is provided on the force applying mechanism 211, and in the embodiment, an internal thread is provided on the power receiving element 212, and an external thread is provided on the force applying mechanism 211. As shown in the figure, the force application mechanism 211 includes a force application part 2111 and a screw 2112 connected thereto, preferably, the force application part 2111 is a motor, the screw 2112 is driven by the motor to rotate forward or backward, and the rotation axis thereof is L5; on the power receiving element 212, a fitting hole 212b1 having an internal thread is provided along the rotation axis L3 from the other end of the columnar body, and the screw 2112 is coaxially fitted with the fitting hole 212b1, that is, the rotation axis L5 of the screw is coaxial with the rotation axis L3 of the power receiving element; it is set that the power receiving member 212 is pushed out by a pushing force generated when the motor is rotated forward, and the power receiving member 212 is pulled back by a pulling force generated when the motor is rotated backward.

In order to ensure the stable operation of the force application mechanism 211, in the embodiment of the present invention, the power transmission device 21 further includes a fixing member 213 for fixing the motor 2111. As shown in fig. 6A, the fixing member 213 is a semi-cylinder, and the radius of the semi-circle formed by cutting along the line perpendicular to the rotation axis L5 is slightly smaller than the radius of the photosensitive drum 22, so that the fixing member can be pressed into the photosensitive drum and can be taken out from the photosensitive drum smoothly, but will not slide in the photosensitive drum; the fixing member 213 includes fixing grooves 2131 formed to be radially expanded on a plane 2130 parallel to the rotation axis L5, and through-hole grooves 2132 provided at both ends in a longitudinal direction of the fixing grooves, the motor 2111 is fixed in the fixing grooves, and the screw 2112 is passed out from one of the through-hole grooves to be engaged with the engaging hole 212b 1.

Example two

Fig. 6B is a partially exploded schematic view of the power transmission device according to the present embodiment. This embodiment is substantially the same as the first embodiment, and therefore, the same components as those in the first embodiment are given the same reference numerals.

In this embodiment, in order to more stably transmit the force generated by the screw 2112 to the power receiving member 212, the power transmission device 21 further includes a nut 214; the third portion 212c of the power receiving part includes a cylindrical table 212c1 provided at the other end of the cylindrical body and coaxial with the power receiving part 212, in addition to a pair of power transmission members 212c2, the engaging hole 212b1 passes through the cylindrical table, and a power transmission surface 212c4 engaged with the nut is provided on an inner wall 212c3 of the cylindrical table 212c 1; meanwhile, in order to prevent the nut from falling off, the power transmission device 21 further includes a protection plate 215 detachably mounted on the fitting hole; in this embodiment, the power transmission member 212c2 may be disposed not only on the column 212b but also on the column base 212c1 in a radially opposite manner, and no matter where the power transmission member is disposed, the power transmission member directly engages with the photosensitive drum 22 to transmit the power received by the first portion 212a to the photosensitive drum, as in the first embodiment.

EXAMPLE III

Fig. 6C is a partially exploded view of the power transmission device according to the present embodiment, and fig. 7 is a sectional view of the power transmission device a-a of fig. 6C. For the sake of understanding, the same components in this embodiment as those in the second embodiment are also given the same reference numerals.

As shown in fig. 6C, the power transmission device 21 relating to the present embodiment further includes a flange cylinder 210 having a rotation axis L4, the rotation axis L4 being coaxial with the rotation axis L3 of the power receiver and the rotation axis L5 of the forcing mechanism; generally, the flange cylinder is fixed to the photosensitive drum 22 by gluing, the force application mechanism 211 is in threaded engagement with the power receiving member 212 in the flange cylinder 22, the power received from the outside by the power receiving member 212 drives the photosensitive member to rotate through the flange cylinder 210, and a gear (not shown) may be further provided on the outer peripheral surface of the flange cylinder and transmits the power to other rotating members through the gear.

The flanged cylinder 210 comprises a flanged cavity 2100 enclosed by the cylinder body, an upper opening 2101, a lower opening 2102 and a protrusion 2105 protruding inwards from the inner wall of the cylinder body in the radial direction, and in order to prevent the power receiving element 212 from falling off from the lower opening 2102, preferably, the flanged cylinder further comprises a bottom plate 2103 integrally formed with the flanged cylinder, wherein the bottom plate 2103 is provided with a bottom plate hole 2104 allowing the screw 2112 to pass through but not allowing the third part 212c of the power receiving element to pass through; of course, the bottom plate 2103 may be a separate component that is attached to the inner wall of the flanged cylinder by gluing, welding, or snapping; as shown in fig. 7, the power receiving member 212 is integrally supported by a bottom plate 2103, a first portion 212a of the power receiving member protrudes from the upper opening 2101, and the power transmission member 212c2 is combined with the protrusion 2105, and when the first portion 212a receives power from the outside, power is transmitted to the flange cylinder by the combination of the power transmission member 212c2 and the protrusion. In this embodiment, in order to better ensure that the rotation axis of the power receiving element 212 is constant during the pushing out, pulling back, and working, the power transmission device further includes a support plate 216, as shown in fig. 6C and 7, the support plate 216 is two integrally semicircular plates, each of which is provided with a semicircular opening through which the second portion 212b of the power receiving element passes when the two plates are put together, and the support plate 216 supports the second portion 212b during the pushing out, pulling back, and working of the power receiving element 212.

Example four

Fig. 8 is a partial sectional view of the power transmission device according to the present embodiment. The present embodiment is a modification of the third embodiment, and therefore, for the convenience of understanding, the same components in the present embodiment as those in the third embodiment are also denoted by the same reference numerals.

In the present embodiment, a movable portion 217 is provided in the flange cylinder 210, the power receiving member is provided in the movable portion, and a fitting hole 2175 to be fitted with the screw 2112 is provided in a lower portion of the movable portion; since the urging mechanism and the power receiving member in the present embodiment are the same as those described in the above-described embodiment, they will not be described again, and the flange cylinder 210 and the movable portion 217 will be described in detail below with reference to fig. 8.

As shown in fig. 8, the power transmission device 21 includes a flange cylinder 210 which encloses a flange cavity 2100 and has an upper opening 2101, a lower opening 2102, and a guide groove 2107 for receiving power, a force application mechanism 211, and a power receiving mechanism combined with the force application mechanism; the power receiving mechanism is located in the flange cavity, and the force applying mechanism and the power receiving mechanism are combined in the flange cavity. In this embodiment, the power receiving mechanism includes a movable portion 217 and a power receiving member 212 carried in the movable portion, the movable portion 217 includes a base 2171 having a certain thickness, a wall 2174 extending from the base in the direction of an upper opening 2101 along a rotation axis L2 of the power transmission device, a power transmission portion 2173 extending radially outward from an outer surface of the wall 2174, and a protrusion 2105 extending radially inward from an inner surface of the wall 2174, the power transmission portion 2173 is engaged with the guide slot 2107 and transmits power, the base 2171 and the wall 2174 enclose to form a receiving cavity 2172, the power receiving member 212 is placed in the receiving cavity 2172, a third portion 212c of the power receiving member is engaged with the protrusion 2105 for transmitting power received from the outside by the first portion 212a to the movable portion 217, and also, to better ensure that the power receiving member 212 is pushed out, pulled back, and during operation, the rotational axis thereof is always constant, and the power transmission device in the present embodiment also includes the support plate 216 as described above.

Since the power receiving member 212 in this embodiment is integrally accommodated in the accommodating chamber 2172, in order to be engaged with the screw 2112, an engaging hole 2175 having an internal thread is provided in the movable portion base 2171; similarly, in order to prevent the power receiving mechanism from coming out of the lower opening 2102 of the flange cylinder, the power transmission device 21 in this embodiment also includes a bottom plate 2103 having a bottom plate hole 2104, and the power receiving mechanism is supported by the bottom plate 2103 as a whole, and in this embodiment, the power receiving mechanism can be pushed out or pulled back as a whole by engaging the screw 2112 with the engaging hole 2175.

Of course, the power transmission device 21 of the present embodiment may also include only the urging mechanism 211 and the power transmission mechanism, as in the above-described embodiment, without including the flange cylinder 210, in which case the power transmission portion 2173 extending radially outward from the outer surface of the wall 2174 is directly engaged with the photosensitive drum 22; alternatively, the power transmission device 21 of the present embodiment may include a nut in addition to the biasing mechanism 211 and the power transmission mechanism, as in the second embodiment, to ensure more stable transmission of the force generated by the screw 2112 to the movable portion 217.

[ Process of coupling Power receiving mechanism to Power take-off Member ]

Fig. 9A to 9C are schematic views showing a process of coupling the power receiving mechanism and the power output member according to the present invention. To facilitate understanding of the present invention, it is necessary here to explain the structure of the power output member 3, and as is common, the power output member 3 is provided in an electrophotographic image forming apparatus and outputs power received from a power source in the electrophotographic image forming apparatus by being combined with the power source. As shown in the figure, the power take-off 3 has a rotation axis L6, and includes a drive shaft 31, a power take-off 32, a power take-off rod 33, and a tapered portion 34, the drive shaft 31, the power take-off 32, and the tapered portion 34 are integrally formed, the power take-off is located between the drive shaft 31 and the tapered portion 34, the power take-off rod 33 is a pin radially penetrating the power take-off, and two ends of the pin are partially located outside the power take-off and are respectively used for being combined with the power receiving surface 212a21 on the power receiving portion 212a2 and transmitting power.

In fig. 9A to 9C, in order to describe the movement of the power receiving element, taking the case of the power transmission device including the flanged cylinder 210 and the power receiving mechanism being the power receiving element 212, only the power transmission device and the power output element are shown, and other components in the process cartridge C are not shown.

As shown in fig. 9A, before the process cartridge loader, the power receiving element 212 is in the retracted state, and the rotational axis L2 of the power transmission device, the rotational axis L3 of the power receiving element, the rotational axis L4 of the flange cylinder, and the rotational axis L5 of the screw are coaxial and parallel to the rotational axis L6 of the power output element. Limited by the structure within the electrophotographic apparatus, even if the power receiving element has only its first portion 212a located outside the flange cylinder, there will be an overlapping area of height h between the highest point of the power receiving portion 212a2 located on the first portion and the lowest point of the tapered portion 34.

In the case where there is no blind spot, i.e., the tapered portion 34 does not interfere with the engagement of the power receiving element 212 with the power output element 3, the power transmitting device is pushed in the direction of the power output element in the direction indicated by the arrow d1 in fig. 9A, the tapered portion 34 passes between the pair of power receiving portions 212a2 to the position shown in fig. 9B, where the power receiving element 212 is opposed to the power output element 3, i.e., the mounting position indicating that the process cartridge has been mounted in the electrophotographic image forming apparatus, and the rotational axis L2 of the power transmitting device, the rotational axis L3 of the power receiving element, the rotational axis L4 of the flange cylinder, the rotational axis L5 of the screw, and the rotational axis L6 of the power output element are coaxial; then the forcing mechanism 211 (described in detail later) is activated, and in the first period of time, the pushing force is applied to the power receiving mechanism by the forcing mechanism, that is, the power receiving element 212 is pushed out by the screw 2112, as shown in fig. 9C, the power receiving element 212 is protruded in the direction indicated by d2, the taper portion 34 of the power output element is completely received by the first portion 212a of the power receiving element, and the power output rod 33 is in contact with or opposed to the power receiving face 212a21, at which time the power receiving mechanism 212 completes the engagement with the power output element 3, and after the first period of time, the forcing mechanism stops operating, and the rotational axis L2 of the power transmitting device, the rotational axis L3 of the power receiving element, the rotational axis L4 of the flange cylinder, the rotational axis L5 of the screw, and the rotational axis L6 of the power output.

[ disengagement Process of Power receiving mechanism from Power output Member ]

Fig. 10A to 10C are schematic views showing a process of disengaging the power receiving mechanism and the power output member according to the present invention. In fig. 10A to 10C, taking the power transmission device including the flanged cylinder 210 and the power receiving mechanism as the power receiving element 212 as an example, only the power transmission device and the power output element are shown in the drawings for describing the movement process of the power receiving element, and other components in the process cartridge C are not shown.

In the case where there is no dead angle, i.e., the tapered portion 34 does not interfere with the disengagement of the power receiver 212 from the power output element 3, when it is necessary to take out the process cartridge from the electrophotographic image forming apparatus due to the completion of the life of the process cartridge or other troubles, both the electrophotographic image forming apparatus and the process cartridge stop operating, the power receiver 212 is in the state as shown in fig. 10A, i.e., the power output lever 33 abuts against the power receiving face 212a21, and the rotational axis L2 of the power transmission device, the rotational axis L3 of the power receiver, the rotational axis L4 of the flange cylinder, the rotational axis L5 of the screw, and the rotational axis L6 of the power output element are coaxial. Then the forcing mechanism 211 (described in detail below) is activated again, and in the second period of time, a pulling force is applied to the power receiving mechanism by the forcing mechanism, i.e., the power receiving element 212 is pulled back by the screw 2112 in the direction indicated by d3, as described above, since the power receiving face 212a21 is planar and parallel to the rotational axis L3 of the power receiving element 212, no resistance is received from the power take-off rod 33 during the process of pulling back the power receiving element 212 by the screw 2112.

As shown in fig. 10B, the power receiving element 212 is in a position opposed to the power output element 33, and the power receiving portion 212a2 is disengaged from the power output rod 33, but the rotational axis L2 of the power transmission device, the rotational axis L3 of the power receiving element, the rotational axis L4 of the flange cylinder, the rotational axis L5 of the screw, and the rotational axis L6 of the power output element are still maintained in a coaxial state; as the operator pulls the process cartridge in the direction indicated by d4, the power receiving element 212 is completely disengaged from the power output element 3, and as shown in fig. 10C, the above-described respective elements are restored to the initial state, i.e., the power receiving element has only the first portion 212a thereof outside the flange cylinder, and the rotational axis L2 of the power transmission device, the rotational axis L3 of the power receiving element, the rotational axis L4 of the flange cylinder, and the rotational axis L5 of the screw are coaxial and parallel to the rotational axis L6 of the power output element.

The process of engaging and disengaging the power receiving mechanism with the power take-off is described above, and as described above, the force application mechanism 211 applies different forces to the power receiving mechanism 212 at different time periods within one cycle of extension and retraction of the power receiving mechanism 212, the one cycle including the first time period, the second time period, and the third time period. In the first time period, the urging mechanism 211 applies a pushing force to the power receiving mechanism 212, and in the second time period, the urging mechanism 211 applies a pulling force to the power receiving mechanism 212; the first time period is the time period from the moment the force application mechanism is started to the moment the power receiving mechanism 212 completes the combination with the power output member 3, and is marked as t 1; the second time period is a time period from when the force application mechanism is activated again until the power receiving mechanism 212 is pulled back to be disengaged from the power output member 3, and is marked as t 2; the sizes of t1 and t2 are determined according to the rotation speed of the screw 2112 and are controlled by a control circuit which is described below, and in the embodiment of the invention, 2s < t1 is taken as t2 < 3 s.

As described above, after the first period of time has elapsed, the operation of the urging mechanism 211 is stopped, and at this time, the power receiving mechanism 21 completes the engagement with the power take-off 3, and when the power take-off 3 receives the power output from the power source, it will rotate about the rotation axis L6, and at the same time, the power take-off lever 33 abuts against the power receiving surface 212a21, and the power is transmitted to the photosensitive drum 22 through the power receiving device 21, so that the photosensitive member 20 starts to operate. Since the urging mechanism 211 has stopped operating at this time, when the photosensitive member 20 receives power to rotate, the urging mechanism 211 rotates coaxially with the photosensitive member; the period of time from the start of rotation of the photosensitive member 20 to the restart of the urging mechanism 211 is defined herein as a third period of time, denoted t3, during which the urging mechanism 211 does not apply any urging force to the power receiving mechanism 212.

[ Power supply and control of urging mechanism ]

The power supply and control means in the forcing mechanism 211 will be described in detail below with reference to fig. 11-14.

FIG. 11 is an exploded view of an electrical contact portion of a photosensitive member according to the present invention; fig. 12 is a schematic view showing the connection of the electric contact portion of the photosensitive member to an external circuit in the present invention.

As described above, the forcing mechanism 211 comprises the motor 2111 and the screw 2112 connected thereto, and in order to control the rotation of the motor 2111, the forcing mechanism 211 further comprises the power supply control assembly 25, the power supply control assembly 25 at least comprises the power supply control circuit 5 and the power cord, the power cord electrically connects the power supply control circuit 5 and the motor 2111, and the power cord and the power supply control circuit 5 are both installed inside the photosensitive drum 22.

Considering that the assembly process of the photosensitive member 20 and the addition of excessive components in the photosensitive drum 22 may affect the developing quality, as another embodiment of the power supply control assembly 25, the power supply control circuit 5 is installed outside the photosensitive member 20, preferably, on the casing of the process cartridge C, and the power supply control assembly 25 in this embodiment further includes a relay portion 26, and the power supply control circuit 5 is connected to the motor 2111 through the relay portion 26. Referring to fig. 11, the transition portion 26 is a first metal ring 263 and a second metal ring 264 having different diameters and fixed to the electrical contact portion 23.

[ Structure of electric contact ]

As shown in fig. 11, the electrical contact portion 23 includes a body 230, and an outer side surface 231 and an inner side surface 232 which are oppositely disposed along the photosensitive member rotation axis L1, the inner side surface 232 being located inside the photosensitive drum 22 and the outer side surface 231 being exposed outside the photosensitive drum 22 when the electrical contact portion 23 is mounted to the photosensitive drum 22.

To achieve the supply of power to the force applying mechanism 211, in particular to the motor 2111, the electrical contact 23 further comprises a first opening 233 and a second opening 234 passing through the electrical contact body along the rotation axis L1, the first opening 233 and the second opening 234 corresponding to the first metal ring 263 and the second metal ring 264, respectively; since the diameters of the first metal ring 263 and the second metal ring 264 are different, when the first metal ring 263 and the second metal ring 264 are concentrically mounted on the electrical contact portion 23, there is no overlapping area therebetween, and the two metal rings may be mounted on both the outer side 231 and the inner side 232 of the electrical contact portion 23, preferably on the outer side 231; in the embodiment of the present invention, in order to save material and enhance the installation stability of the metal rings, as shown in fig. 11, the electrical contact 23 further includes a first annular groove 2311 and a second annular groove 2312 which are provided on the outer side surface 231 and are recessed toward the inner side surface along the rotation axis L1, and the first metal ring 263 and the second metal ring 264 are fixedly installed in the first annular groove 2311 and the second annular groove 2312, respectively.

[ connection of electric contact to external Circuit ]

As shown in fig. 12, before the electrical contact portion 23 is connected to an external circuit, the motor 2111 needs to be electrically connected to the metal ring (not shown in fig. 12), specifically, positive and negative power lines of the motor 2111 are led out from the other through hole 2132 of the fixing member shown in fig. 6A to 6C and respectively pass through the first opening 233 and the second opening 234, so as to be electrically connected to the metal ring.

As shown in fig. 12, the external circuit is a power supply control circuit 5, and two output terminals of the circuit are respectively in electrical communication with two metal rings, specifically: both output terminals of the circuit, which are preferably fixed to the process cartridge housing, slide against the surface of the metal ring when the electric contact 23 integrally rotates with the photosensitive member, are kept fixed. As described above, since the motor 2111 is already in electrical communication with the metal ring, that is, the motor is in electrical communication with the power supply control circuit 5 through the metal ring, the motor 2111 can receive the electric power output by the power supply control circuit 5, and the forward and reverse rotation of the motor 2111 is controlled by the circuit.

In the third period, the force application mechanism 211 rotates coaxially with the photosensitive member 20, and it is apparent that the positive and negative power supply lines of the motor 2111 also rotate together, however, since the above-described first opening 233 and second opening 234 are provided, the positive and negative power supply lines also pass through the first opening 233 and second opening 234, respectively, and are electrically communicated with the first metal ring 263 and the second metal ring 264 provided in the first annular groove 2311 and the second annular groove 2312, the positive and negative power supply lines are already integrated with the photosensitive member 20, and are relatively stationary, and rotate together when the photosensitive member 20 rotates, thereby avoiding the disadvantage that the positive and negative power supply lines wind up.

[ Power supply control Circuit ]

Example one

Fig. 13 is a block diagram of the power supply control circuit in the present embodiment. The power supply control circuit 5 comprises a main power supply 50, a first switch circuit 51, a second switch circuit 52, a voltage boosting circuit 53, a voltage reducing circuit 54, a trigger device 55, a control circuit 56 and a forward/reverse driving circuit 57, wherein the input end of the first switch circuit 51 and the input end of the second switch circuit 52 are connected with the main power supply 50; the input end of the first switch circuit 51 is connected with the input end of the booster circuit 53; the output terminal of the second switching circuit 52 is connected to the input terminal of the control circuit 56; the input end of the voltage reduction circuit 54 is connected with the output end of the voltage boost circuit 53, and the output end thereof is connected with the input end of the second switch circuit 52; the input terminal of the control circuit 56 is further connected to the triggering device 55, and the output terminal thereof is simultaneously connected to the input terminal of the first switching circuit 51 and the input terminal of the forward/reverse driving circuit 57; the input terminal of the forward/reverse drive circuit 57 is also connected to the output terminal of the booster circuit 53, and the output terminal thereof is connected to the forcing mechanism 211 as the output terminal of the power supply control circuit 5.

In the embodiment of the present invention, the main power source 50 is a battery, the triggering device 55 is preferably a button, and can be installed at any position of the casing of the processing box, and for more reliable operation, the button 55 is preferably installed on the terminal surface 11 (as shown in fig. 4) in the machine direction of the processing box, and is triggered when the door body of the electrophotographic image forming apparatus is closed; in addition, the second switch circuit 52 is preferably a single-pole double-throw switch, and ensures that the control circuit 56 is communicated with any one of the main power supply 50 and the voltage-reducing circuit 54 at any time; since the voltage of the main power supply 50 is between the operating voltage of the forward/reverse drive circuit 57 and the operating voltage of the control circuit 56, the power supply control circuit 5 requires not only the step-up circuit 53 but also the step-down circuit 54.

The operation of the power supply control circuit 5 is described below with reference to fig. 9, 10, and 13:

(1) before the door body is closed before or after the process cartridge is installed, the key 55 is not pressed, and the control circuit 56 does not detect the trigger signal, so that the control circuit 56 sends an off signal to the first switch circuit 51, the main power supply 50 is disconnected from the booster circuit 53, the single-pole double-throw switch 52 connects the main power supply 50 with the control circuit 56, the main power supply supplies power to the control circuit 56, the control circuit 56 is in a sleep state at the time, the forward/reverse rotation driving circuit 57 does not work, and the power receiving part 212 corresponds to the retraction state shown in fig. 9B.

(2) When the operator closes the door body and presses the key 55, the control circuit 56 detects the trigger signal, and sends a closing signal to the first switch circuit 51, the main power supply 50 is communicated with the voltage-increasing circuit 53, at this time, the single-pole double-throw switch 52 communicates the voltage-decreasing circuit 54 with the control circuit 56, the voltage-increasing circuit 53 supplies the increased voltage to the forward/reverse rotation driving circuit 57 and the voltage-decreasing circuit 54, the voltage-decreasing circuit 54 reduces the voltage and supplies the voltage to the control circuit 56, the control circuit 56 sends a forward rotation signal to the forward/reverse rotation driving circuit 57, finally, the forward/reverse rotation driving circuit 57 drives the force-applying mechanism 211 to operate, the motor 2111 in the force-applying mechanism 211 rotates forward, and the power receiving piece 212 is pushed out to the extended state shown in fig. 9C, that is, the power receiving piece 212 is combined with the power output piece.

The time required for the process is the first time period t1, and the value of t1 can be calculated according to the stroke of the power receiving element 212 and the parameters such as the rotation speed and the thread pitch of the screw 2112, of course, the value of t1 is not limited to a certain fixed value, and can be properly adjusted in a control program according to actual needs.

(3) After the control circuit 56 controls the first switch circuit 51 to be closed for t1 time, the control circuit 56 sends an off signal to the first switch circuit 51 again, the main power supply 50 is disconnected with the boosting circuit 53 again, and the single-pole double-throw switch 52 connects the main power supply 50 with the control circuit 56 again, so that the control circuit 56 is in a sleep state again; the power receiving element 212 is pushed out to be combined with the power output element 3, the force application mechanism 211 stops working, and the photosensitive element 20 can be driven by the power output element 3 to rotate; since the door body is always pressing the key 55, the control circuit 56 will always be in the sleep state unless the key 55 is no longer pressed.

The time required for this process is the third time period t3, and as can be seen from the above, the value of the time period t3 is not a fixed value, but depends on when the key 55 is no longer pressed, and in the time period t3, the force application mechanism 211 does not apply any force to the power receiving mechanism 212 because the force application mechanism 211 does not work.

(4) When the door body is opened, the key 55 is not pressed any more, the control circuit 56 detects the trigger signal, and sends a closing signal to the first switch circuit 51 again, the main power supply 50 is communicated with the voltage boosting circuit 53, at this time, the single-pole double-throw switch 52 communicates the voltage reducing circuit 54 with the control circuit 56 again, as described in (2), the voltage boosting circuit 53, the voltage reducing circuit 54, the control circuit 56 and the forward/reverse driving circuit 57 all start to operate, only at this time, the control circuit 56 sends a reverse signal to the forward/reverse driving circuit 57, and accordingly, the motor 2111 reverses, and the power receiving part 212 is pulled back to the retraction state shown in fig. 10B.

The time required for this process is the second time period t2, and generally, the stroke of the power receiving element 212 being pushed out and pulled back is the same, so t2 is t 1.

(5) After the control circuit 56 controls the first switch circuit 51 to be closed for t2, an open signal is sent to the first switch circuit 51 again, and the circuits in fig. 13 return to the initial state described in (1).

As can be seen from the above, in one cycle of the extension and retraction of the power receiving mechanism 212, the third time period t3 is between the first time period t1 and the second time period t2, and the process of applying the acting force to the power receiving mechanism 212 by the force applying mechanism 211 is the first time period t1, the third time period t3 and the second time period t2 in sequence.

Example two

Fig. 14 is a block diagram of the power supply control circuit in the present embodiment. To prevent the disadvantage that the forward/reverse driving circuit 37 in fig. 13 will not work when the battery power is exhausted in the first embodiment, and eventually the power receiving element 212 cannot be pulled back, the present embodiment adds the backup power supply 58 and the backup power supply switching circuit 59 to the first embodiment.

As shown in fig. 14, the main power source 50 and the backup power source 58 are connected through a backup power source switching circuit 59, the backup power source switching circuit 59 is also connected to the voltage boosting circuit 53, the backup power source 38 is connected to the forward/reverse driving circuit 57, in this embodiment, the backup power source 58 outputs a voltage for not only driving the forward/reverse driving circuit 57 but also indicating a reverse signal, and the backup power source 38 outputs a voltage lower than a voltage required for the forward/reverse driving circuit 57 to operate.

When the main power source 50, i.e., the battery, is exhausted, the backup power source switching circuit 59 disconnects the main power source 50 and connects the backup power source 58 and the voltage boosting circuit 53, the voltage step-down circuit 54 and the control circuit 56 will not operate, the voltage output from the backup power source 58 is boosted by the voltage boosting circuit 53 and then supplied to the forward/reverse driving circuit 57, and as described above, the voltage output from the backup power source 58 is also a reverse signal with respect to the forward/reverse driving circuit 57, and therefore, the forward/reverse driving circuit 57 drives the motor 2111 to reverse, so that the power receiving element 212 is disengaged from the power output element 3.

[ description and resolution of the dead-space position of installation and off-line ]

[ dead angle positions of machine loading and unloading ]

Fig. 15A is a schematic view showing a state where the power transmission device is in a blind spot position during installation, and fig. 15B is a schematic view showing a state where the power transmission device is in a blind spot position during offline.

As shown in fig. 15A, when the power transmission device 21 is mounted in the direction d1, the connecting line of the two power receiving portions 212a2 is in a position parallel to d1, and as described above, there is an overlapping region with a height h (as shown in fig. 9A) between the highest point of the power receiving portion 212a2 and the lowest point of the tapered portion 34, and therefore, when the power receiving portion located downstream in the direction d1 is opposed to the tapered portion 34, an installation dead space occurs, that is, the tapered portion 34 interferes with the mounting of the power transmission device 21.

As shown in fig. 15B, the power transmission device 21 is pulled in the direction indicated by d4, and the connecting line of the two power receiving portions 212a2 is also in a position parallel to d4, and the tapered portion 34 interferes with the detachment of the power transmission device 21, as in the above-described dead space.

[ solution to solve dead Angle position ]

FIG. 16 is a block diagram of the circuitry used by the present invention to resolve dead-angle positions; FIGS. 17A-17C are schematic views of a process for solving dead corners of the installation; FIGS. 18A-18C are schematic views of a process for solving offline deadspace.

As shown in the figure, the present invention adds a detection circuit 60 to the power supply control circuit 5, the detection circuit 60 is respectively communicated with the voltage reduction circuit 54 and the forward/reverse rotation driving circuit 57, and the detected piece 218 is mounted on the power receiving part 212a2 or the disk 212a1, when the detection circuit 60 detects the detected piece 218, the forward/reverse rotation driving circuit 57 is sent a forward or reverse rotation signal to force the power receiving part to rotate a certain angle, thereby avoiding the dead angle position.

Since this solution adds a corresponding circuit to the first or second embodiment, this solution can be used as the third embodiment of the power supply control circuit 5.

In the present embodiment, the detection circuit 60 is a magnetic induction circuit including a hall sensor (not shown), the detected member 218 is a magnet, as shown in fig. 17A, the magnetic induction circuit 60 is mounted on the stand 24 at a position close to the power receiving member 212, and the magnetic induction circuit 60 is located on the on-line and off-line paths; the magnet 218 is mounted on the disk 212a1 or the power receiving portion 212a2, and when the magnet 218 is mounted on the disk 212a1, it is preferable that the magnet 218 is located in a range where the projection center of the power receiving portion 212a2 on the disk is deviated by 30 ° in the disk circumferential direction.

When the process cartridge is mounted in the direction d1 in fig. 17A, the magnet 218 is located at the position directly above or slightly off-angle from the magnetic induction circuit 60 when the power receiving part 212a2 is located at the dead angle position, and at this time, the magnet 218 is detected by the magnetic induction circuit 60, and as described above, the magnetic induction circuit 60 sends the forward rotation or reverse rotation signal to the forward/reverse rotation driving circuit 57, and as shown in fig. 17B, the power receiving part 212 rotates in the direction r1 by a certain angle so as to avoid the mounted dead angle position, and the process cartridge is mounted continuously in the direction d1, and when the mounting position is reached, the power receiving part 212 is pushed out by the urging mechanism to be coupled to the power take-off 3, as shown in fig. 17C.

If the process cartridge is required to be taken out, just at the position shown in fig. 18A, i.e., the line connecting the two power receiving parts 212a2 is parallel to the loading direction d1 or the unloading direction d4, as shown in fig. 18A, first, the urging mechanism applies a pulling force to the power receiving part 212 so that the power receiving part is pulled back to the position shown in fig. 18B in the direction shown by d3, at which time the power transmission device is in the escape blind spot position; since the magnet 218 is mounted at the corresponding position of the power receiving part 212a2 or the disk, the magnetic induction circuit 60 on the bracket 24 detects the presence of the magnet 218, as mentioned above, the magnetic induction circuit 60 will send a forward or reverse rotation signal to the forward/reverse rotation driving circuit 57, and the power receiving part 212 is driven to rotate in the direction r2 by a certain angle, so as to avoid the offline dead angle position, as shown in fig. 18C, the tapered part 34 of the power output part 3 will not interfere with the movement of the power receiving part in the direction d4, and the cartridge can be taken out smoothly.

The force applying element 2111 of the force applying mechanism 211 in the above embodiment is a motor, but it may be a force transmitting element engaged with the screw 2112, for example, including a gear fixed on the opposite end of the screw from the power receiving element, and manually rotating the screw to push out or pull back the power receiving element 212.

As described above, the force application mechanism 211 applies different action modes to the power receiving mechanism 212 at different time periods, and when the power receiving mechanism 212 is connected with the photosensitive drum through the flange cylinder and transmits power, the power receiving mechanism 212 can be effectively prevented from falling off without arranging the barb part on the protruding part 2105 of the flange cylinder 210 at a position close to the opening of the flange cylinder; since there is no need to precisely control the distance between the barbed portions because of the absence of the barbed portions, the manufacturing accuracy of the power transmission device 21 in the process cartridge is not so high.

Claims (8)

1. A process cartridge detachably mountable to an electrophotographic image forming apparatus having a power take-off, said process cartridge comprising a cartridge housing and a photosensitive member mounted in the housing, said photosensitive member having a rotational axis L1, including a photosensitive drum, and a power transmitting device connected to the photosensitive drum, said power transmitting device including a force applying mechanism and a power receiving mechanism cooperating with each other, the power receiving mechanism being extended and retracted along the rotational axis L1 by the force applying mechanism, characterized in that the force applying mechanism applies different forces to the power receiving mechanism at different time periods during one cycle of extension and retraction of the power receiving mechanism;

the one cycle includes a first period t1 and a second period t 2;

in a first time period t1, the force application mechanism applies thrust to the power receiving mechanism, and after the first time period t1 elapses, the force application mechanism stops working;

at a second time period t2, the force application mechanism is started again and applies pulling force to the power receiving mechanism;

the force application mechanism comprises a force application part and a screw connected with the force application part, and the power receiving mechanism is a power receiving part in threaded fit with the screw.

2. A cartridge according to claim 1, wherein said one cycle further includes a third period t3, said third period t3 being between the first period t1 and the second period t 2.

3. A process cartridge according to claim 2, wherein said urging mechanism applies the urging force to the power receiving mechanism in the order of: a first time period t1, a third time period t3, and a second time period t 2.

4. A cartridge according to claim 3, wherein the urging mechanism does not apply any urging force to the power receiving mechanism during the third period.

5. A process cartridge according to claim 4, wherein said first period t1 is a period from when the urging mechanism is actuated until the power receiving mechanism completes engagement with the power take-off; the second time period t2 is the time period from when the force application mechanism is activated again until the power receiving mechanism is pulled back out of engagement with the power take-off; the third time period t3 is a time period from when the photosensitive member starts to rotate to when the urging mechanism is activated again.

6. A process cartridge according to claim 5, wherein said first period t1 satisfies: 2s < t1 < 3 s.

7. A process cartridge according to claim 5, wherein said second period of time t2 satisfies: 2s < t2 < 3 s.

8. A process cartridge according to claim 6 or 7, wherein said first time period t1 and second time period t2 further satisfy: t1 ═ t 2.

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