BR112013009100B1 - STEERING FORCE TRANSMISSION MECHANISM AND PROCESS CARTRIDGE CONTAINING IT - Google Patents

Abstract

TARGETING FORCE TRANSMISSION MECHANISM AND PROCESS CARTRIDGE CONTAINING THEREOF, which comprises a photosensitive drum steering member, wherein the photosensitive drum steering member is engaged with an imaging apparatus steering member and receives the steering force of the directing apparatus of the image forming apparatus; the steering member of the image forming apparatus comprises a triangular groove having a triangular cross section and a steering force transmitting part disposed at three apex angles of the triangular groove; the photosensitive drum directing member comprises a distortion-free protuberance extending axially from the rear face of a drum shaft and engaging with the groove on the directing member of the image forming apparatus; the protrusion has a position limiting mechanism and a tensioning mechanism; a projecting tooth arranged in an oblique position on the aforementioned protuberance without distortion is taken as a tensioned mechanism; and each projecting tooth also has a mating surface that is engaged with the driving force transmission component to transmit the force (...).

Description

Field of Invention

[001] The present invention relates to an image forming apparatus such as a laser printer and copying machine, particularly to a drive force transmission mechanism applied to the image forming apparatus and a process cartridge which uses.

Background of the Invention

[002] The traditional image forming apparatus is equipped with a motor, an image forming apparatus driving member and a process cartridge, wherein the process cartridge can be detachably mounted to the image forming apparatus ; and a photosensitive cylinder is disposed on the process cartridge. During operation of the imaging apparatus, the driving force is generated by the motor and transmitted to the process cartridge through the driving member of the imaging apparatus such that the photosensitive cylinder on the process cartridge be directed to rotate.

[003] As illustrated in Figs. 1 and 2, a drive force transmission mechanism is fixedly disposed at one end of the photosensitive cylinder 7 and comprises a cylinder shaft 17; a distortion protuberance 17a is disposed on the cylinder axis 17 and has a rear part 17a1; the center of rotation of the cylinder axis 17 coincides with the center of rotation of the photosensitive cylinder 7; and the driving member of the imaging apparatus 18 is equipped with a distortion groove 18a having a lower surface 18a2.

[004] During operation of the image forming apparatus, the driving member of the image forming apparatus 18 receives the rotary drive force of the motor; the cylinder shaft 17 is engaged with the driving member of the image forming apparatus 18; and the rotating driving force is transmitted to the axis of the cylinder 17 through the driving member of the image forming apparatus 18 and ultimately drives the photosensitive cylinder 7 to rotate. When the cylinder shaft 17 is engaged with the image forming apparatus drive member 18, the distortion protuberance 17a on the cylinder shaft 17 is interposed into the distortion groove 18a on the image forming apparatus drive member. 18; the rear part 17a1 lies against the lower surface 18a2; and the rotational driving force of the driving member of the image forming apparatus 18 is transmitted to the cylinder shaft 17 through the engagement between the distortion protuberance 17a and the groove 18a.

[005] Figs. 3 and 4 are cross-sectional diagrams respectively illustrating the state in which the distortion protuberance 17a and the distortion groove 18a do not rotate and rotate. As illustrated in the figures, cross sections of the distortion protrusion 17a and the distortion groove 18a are both triangular (such as equilateral triangles) and the dimension of the triangular protrusion 17a is smaller than that of the triangular groove 18a. As illustrated in Fig. 3, when the protrusion 17a is interposed in the groove 18a and does not rotate together with the groove 18a, an axis of rotation XI of the cylinder axis on the photosensitive cylinder is not coincident with an axis of rotation X2 of the member drive of the image formation device. As illustrated in Fig. 4, when the protrusion 17a is engaged with the groove 18a and rotates together with the groove 18a, three apex angles 17a2 of the triangular protrusion 17a are engaged with the three ends of the triangle of the groove 18a and the force of drive is transmitted to the protrusion 17a of the groove 18a. At this point, the rotation axis XI of the cylinder axis of the photosensitive cylinder is coincident with the rotation axis of 18a distortion during operation can be guaranteed. In the figure, RO designates the diameter of the circle of rotation of the three apex angles 17a2 of the protuberance 17a; RI designates the inscribed circle diameter of the triangular groove 18a; and R2 designates the diameter of the rotating circle of three apex angles of the groove 18a. In order to achieve drive force transmission between the protuberance 17a and the drive member of the image forming apparatus 18a, RO, RI and R2 must meet the following condition: RI < RO < R2.

[006] Fig. 5 is another embodiment of the prior art. In the embodiment, the distortion bulge 17a and the distortion groove 18a are quadrilaterals (such as regular quadrilaterals) and the quadrilateral bulge 17a and the quadrilateral groove 18a are fitted together and used to direct the transmission of force.

[007] The drive member of the image forming apparatus in the prior art may also adopt the means as illustrated in Fig. 6. As illustrated in Fig. 6, a distortion groove 28a is arranged at one end of the drive member of the image forming apparatus 28 and equipped with a lower surface 28a1 and a support protuberance 28a2 which is disposed in the center of the triangular distortion groove 28a (the center of rotation of the support column protuberance 28a2 coincides with an axis of rotation of the driving member of the image forming apparatus); the height of the supporting protrusion 28a2 is basically identical to the depth of the groove 28a; and said support column may be conical.

[008] The photosensitive cylinder provided with the drive force transmission mechanism is generally applied to a process cartridge for traditional image forming apparatus. Said process cartridge comprises at least the photosensitive cylinder which is used for forming an electrostatic latent image and is equipped with the driving force transmission mechanism, a developer which is used to develop the electrostatic latent image and a development that is used to transmit the developer to the photosensitive cylinder. When said process cartridge is mounted on the image forming apparatus, the rotary driving force of the motor on the image forming apparatus is received by said driving member of the image forming apparatus such that the cylinder photosensitive sensor and the developing roller are directed to rotate.

[009] The drive force transmission mechanism in the prior art has the disadvantages that: 1. When the distortion protrusion is engaged with the distortion groove, the distortion angle of distortion surfaces on the protrusion and the groove needs to have high precision. When the distortion angle is inconsistent due to the manufacturing precision of the distortion surfaces on the protrusion and groove, the distortion surfaces on the protrusion and groove make point-to-surface contact and a distortion surface may be deformed during fitting between the protrusion and the groove in such a way that the axis of rotation XI of the cylinder axis on the photosensitive cylinder cannot coincide with the axis of rotation X2 of the driving member of the imaging apparatus and therefore may be affected Stable drive force transmission. In order to solve the aforementioned problem, the manufacturing precision of the protrusion and groove distortion surfaces needs to be high, so as to increase the manufacturing cost and cause problems such as manufacturing difficulty. 2. Polygonal shapes of the bulge and groove are difficult to process, and the manufacturing precision of the bulge and groove needs to be high. With an equilateral triangle as an example, the accuracy of the equilateral triangle protrusion and the equilateral triangle groove needs to be high, so as to be able to guarantee the accuracy of the triangular center. On the other hand, the rotation axis XI of the cylinder axis of the photosensitive cylinder may not coincide with the rotation axis unstable. Furthermore, during engagement between the protuberance and the groove, apex angles of the triangle on the protuberance tend to be deformed after tension due to the need to transmit driving force and tend to be worn out or damaged after long-term operation. Additionally, as the three apex angles of the triangle also have the functions of tension rotation, support and positioning during operation, the phenomenon of lack of coincidence of the XI and X2 centers tends to occur during the fit between the worn or damaged triangle and the groove and therefore stable transmission may be affected. In order to ensure transmission accuracy and stability, therefore, the hardness and wear resistance of the triangular protuberance materials need to be high. On the other hand, since the positions at which the ends of the triangular groove contact the three apex angles of the protrusion also tend to be damaged or worn during operation, the hardness and wear resistance of the triangular groove also need to be high.

Summary of the Invention

[010] The present invention provides a drive force transmission mechanism to solve the technical problem that the fit between a protuberance and a groove may be affected by the fact that the tensioned mechanism may be worn out due to excessive pressure during fit. between the tensioned mechanism and the groove.

[011] To solve the problem, the present invention adopts the technical solution that: The present invention relates to a drive force transmission mechanism, which comprises a photosensitive cylinder drive member, wherein the drive member of photosensitive cylinder is engaged with a driving member of the image forming apparatus to transmit the driving force; the image forming apparatus comprises a triangular slot having a triangular cross-section and a driving force transmission part disposed at three apex angles of the triangular slot; the photosensitive cylinder drive member comprises a distortion-free protuberance extending axially from the rear face of a cylinder shaft and engaging with the groove over the drive member of the image forming apparatus; the protrusion has a position limiting mechanism and a tensioning mechanism; a projecting tooth arranged in an oblique position on the protuberance without distortion is taken as a tensioned mechanism; and each of said projecting teeth also has a mating surface which is engaged with the . driving force transmission part to transmit the driving force.

[012] The position limiting mechanism and the tensioning mechanism are arranged in different positions.

[013] A support disc arranged over the protrusion and fitted with the ends of the groove is considered a position limiting mechanism.

[014] The number of teeth in projection is two; and the two projecting teeth are fitted, respectively, with two of the driving force transmission parts arranged in the three apex angles of said groove.

[015] The angle included between said projecting teeth and an axis of rotation of the photosensitive cylinder drive member is 3° to 40°.

[016] The angle included between the oblique projecting teeth and the axis of rotation of the photosensitive cylinder drive member is 25° to 30°.

[017] The support disc is placed over the protrusion; and the length of each protruding tooth starting from the bulge-bearing disc without distortion along the radial direction is 2 to 5 mm.

[018] The length of each tooth in projection from the bulge supporting disc without distortion along the radial direction is 2.3 to 3.3 mm.

[019] The minimum included angle between the two projecting teeth is 120°; and the upper limit tolerance of manufacturing accuracy of the included angle is 2° to 10°.

[020] The upper limit tolerance of the manufacturing accuracy of the angle included is 2° to 4°.

[021] Each projection tooth also has two parallel planes that are connected to the support disc; and the mating surface lies at an angle included with the two parallel planes.

[022] The angle included between tapered ends of the mating surfaces and a photosensitive cylinder axis is 5° to 50°.

[023] The angle included between the tapered ends of the fitting surfaces and the photosensitive cylinder axis is 10° to 40°.

[024] Each fitting surface has two straight ends; and the angle included between the straight end and a connecting line of the center of the photosensitive cylinder drive member and an apex angle of each projecting tooth is from 0° to 90°.

[025] The angle included between the straight end and the connecting line of the center of the photosensitive cylinder drive member and the apex angle of each projecting tooth is 25° to 45°.

[026] The area of the fitting surface is 5 to 20 mm2.

[027] The area of the fitting surface is 7 to 16 mm2.

[028] The position limiting mechanism has a support hole that is disposed on the protrusion and in a central axis of the cylinder axis and a support protuberance that is disposed in a central axis in the groove and fitted with the limiting hole .

[029] The support disk and two protrusion columns are arranged on the protrusion; the bulge columns are distributed symmetrically on both sides of the bulge; a first protruding column is a projecting tooth engaged with the drive force transmission component; a second protruding column makes contact with the inner wall of the groove; the first protruding column is taken as the tensioned mechanism; and the position limiting mechanism comprises the support disc and the second protruding column.

[030] The present invention relates to a process cartridge, which comprises a photosensitive cylinder and also comprises the drive force transmission mechanism that is disposed on the end of the photosensitive cylinder.

[031] When adopting the technical solution, as the position limiting mechanism and the tensioning mechanism are arranged in different positions, the position limiting mechanism cannot affect the coincidence of rotation centers during fitting due to excessive pressure of the tensioned mechanism when engaged with the groove, and in this way, the technical problem in the traditional drive force transmission mechanism that the fit between the protuberance and the groove may be affected by the fact that the tensioned mechanism may wear out can be solved. due to excessive pressure when fitted with the groove. Furthermore, as the number of projecting teeth is two and the two projecting teeth are fitted respectively with two drive force transmission parts of the three apex angles, the drive force of the device drive member is imaging apparatus and the photosensitive cylinder driving member at various positioning points can be reduced and in this way the wear of the imaging apparatus driving member and the photosensitive cylinder driving member can be reduced and consequently , the technical problem that the positioning may be affected by the fact that the axis centers of the driving member of the imaging apparatus and the driving member of the photosensitive cylinder are not coincident with each other due to wear can be solved.

[032] The technical solution also has the advantages that: 1. Protuberances with the same structure can be fitted with grooves with different shapes, in order to achieve the transfer of driving force. 2. By adopting the above shapes, the protrusions are easier to process and the need for manufacturing precision is lower. 3. Support points and tension points on the protrusion are separated from each other in such a way that the support points on the protrusion cannot affect the coincidence of rotation centers X1 and tension on the protrusion by fitting it with the groove. 4. The protuberance and groove may be tapered, such that the protuberance can be interposed more easily into the groove. 5. As the tooth projecting over the protuberance is arranged obliquely over the supporting disc, the phenomenon of disengagement of the drive member of the photosensitive cylinder from the drive member of the image forming apparatus during transmission of images can be avoided. driving force and therefore stable driving force transmission can be realized between the driving member of the image forming apparatus and the driving member of the photosensitive cylinder, 6. Several teeth in oblique projection can also be arranged on the bulge, such that the number of stress points between the bulge and the groove can be reduced. 7. By arranging the mating surfaces over the projecting teeth, the tension area between the protuberance and the groove can be increased, the wear produced between the protuberance and the groove can thus be reduced and, consequently, it can be more stable drive force transmission is realized between the photosensitive cylinder drive member and the image forming apparatus drive member.

Brief Description of Figures

[033] Fig. 1 is a stereogram of a photosensitive cylinder equipped with a photosensitive cylinder drive member in the prior art.

[034] Fig. 2 is a stereogram of the photosensitive cylinder driving member and a driving member of the image forming apparatus in the prior art.

[035] Fig. 3 is a cross-sectional diagram illustrating the state in which a distortion protuberance and a distortion groove in the prior art do not rotate.

[036] Fig. 4 is a cross-sectional diagram illustrating the state in which the distortion protuberance and the distortion groove in the prior art rotate.

[037] Fig. 5 is a schematic diagram illustrating the state in which another protuberance and another groove in the prior art have a quadrilateral shape.

[038] Fig. 6 is a schematic diagram illustrating the state in which a positioning column is arranged in the center of the groove in the prior art.

[039] Fig. 7 is a stereogram of the driving member of the image forming apparatus.

[040] Fig. 8 is a top view of the driving member of the imaging apparatus.

[041] Fig. 9 is a stereogram illustrating the state before engagement between a photosensitive cylinder drive member and a drive member of the image forming apparatus in embodiment 1.

[042] Figs. 10a and 10b are cross-sectional diagrams illustrating the state in which a distortion-free protuberance and a distortion groove in embodiment 1 are fitted together.

[043] Fig. 11 is a cross-sectional diagram illustrating the state in which a protuberance and a groove in embodiment 2 are fitted together.

[044] Figs. 12a and 12b are cross-sectional diagrams illustrating, respectively, the state in which an undistorted protuberance and a distortion groove in embodiment 3 are fitted together if the groove is a quadrilateral and a pentagon.

[045] Figs. 13a and 13b are cross-sectional diagrams illustrating the state in which a distortion-free protuberance equipped with a support column and a distortion groove in embodiment 4 are fitted together.

[046] Figs. 14a and 14b are cross-sectional diagrams illustrating, respectively, the state in which a protuberance and a groove in embodiment 5 and embodiment 6 are fitted together if the protuberance is a quadrilateral and a pentagon.

[047] Fig. 15 is a stereogram illustrating the state before engagement between a groove equipped with a positioning column and a photosensitive cylinder drive member in embodiment 7.

[048] Fig. 16 is a stereogram of a photosensitive cylinder equipped with a positioning hole in embodiment 7.

[049] Figs. 17a, 17b and 17c are cross-sectional diagrams illustrating the state in which protrusions with three different shapes equipped with positioning holes are fitted with a groove equipped with a positioning column, in embodiment 7.

[050] Fig. 18 is a stereogram of a photosensitive cylinder drive member in embodiment 8.

[051] Fig. 19 is a force diagram illustrating the assembly of the photosensitive cylinder drive member and an image forming apparatus drive member in embodiment 8.

[052] Fig. 20 is a stereogram of a photosensitive cylinder drive member in embodiment 9.

[053] Fig. 21 is a front view of the photosensitive cylinder drive member in embodiment 9.

[054] Fig. 22 is a top view illustrating the assembly of the photosensitive cylinder drive member and a drive member of the image forming apparatus in embodiment 9.

[055] Fig. 23 is an assembly diagram of the photosensitive cylinder drive member and the image forming apparatus drive member in embodiment 9.

[056] Fig. 24 is a cross-sectional force diagram illustrating the state after engagement between the driving member of the imaging apparatus 10 and the photosensitive cylinder driving member in embodiment 9.

[057] Fig. 25 is a stereogram of a photosensitive cylinder drive member in embodiment 10.

[058] Fig. 26 is a stereogram of a photosensitive cylinder drive member in embodiment 11.

[059] Fig. 27 is a partial enlarged drawing of an undistorted protuberance equipped with mating surfaces in accordance with the present invention.

[060] Fig. 28 is a front view of Fig. 26 along “B”.

[061] Fig. 29 is a top view of the undistorted protuberance equipped with the engaging surfaces in accordance with the present invention.

Detailed Description of Preferred Accomplishments Achievement 1:

[062] The present invention relates to a drive force transmission mechanism, which comprises a photosensitive cylinder drive member, wherein the photosensitive cylinder drive member is engaged with a drive member of the photoforming apparatus. images and receives the driving force from the driving member of the imaging apparatus; a groove is disposed on the driving member of the imaging apparatus; the photosensitive cylinder drive member comprises a protuberance extending axially from the rear face of a photosensitive cylinder shaft; and the limitation between the protuberance and the groove can be carried out by means of a mutual contact position limiting mechanism and the transmission of the driving force can be carried out by means of a tensioned mechanism.

[063] Figs. 7 and 8 are, respectively, a stereogram and a top view of the driving member of the image forming apparatus. As illustrated in the figures, the driving member of the image forming apparatus 18 comprises a distortion groove 18a having a triangular cross-section and a driving force transmission part 18b disposed at the three apex angles of the triangle and the transmission part driving force 18b is composed of internal chamfers arranged at the apex angles of the triangle and below in the flow direction of rotation of the driving member of the image forming apparatus.

[064] Fig. 9 is a stereogram illustrating the state before engagement of the photosensitive cylinder drive member and the drive member of the image forming apparatus. As illustrated in the figure, the photosensitive cylinder drive member comprises a cylinder flank 26 disposed on the end of a photosensitive cylinder 7 and a cylinder axis 27 and a distortion-free protuberance 27a extending axially from the rear part of the flank. cylinder 26 and are used to support the photosensitive cylinder 7 in rotation during the operation of a process cartridge, wherein a support disc 27a2 and a projecting tooth 27a1 are disposed on the distortion-free protuberance 27a. In the embodiment, the support disc 27a2 and the projecting tooth 27a1 are taken, respectively, as the position limiting mechanism and the tensioned mechanism of the drive force transmission mechanism. The distortion-free protuberance 27a can be engaged with the distortion groove 18a. When the projecting tooth 27a1 and the supporting disc 27a2 on the protrusion 27a are interposed in the groove 18a, the protuberance 27a is engaged with the groove 18a and receives the rotary drive force of the groove 18a. When a motor on the imaging apparatus rotates, therefore, the driving force is transmitted to the driving member of the imaging apparatus 18 through the motor and to the photosensitive cylinder driving member through the fitting between the distortion-free protuberance 27a and the distortion groove 18a, and finally, the photosensitive cylinder 7 is directed for rotation. The cross section of the distortion groove 18a is a triangle (such as an equilateral triangle).

[065] Fig. 10a is a cross-sectional diagram illustrating the state in which the distortion-free protuberance 27a is fitted into the distortion groove 18a. As shown in the figure, when the distortion-free protrusion 27a is fitted with the distortion groove 18a, the support disc 27a2 on the distortion-free protrusion 27a is tangent to three ends of the groove 18a, in order to ensure precise centering of the protrusion. 27a and groove 18a. At this point, a rotation axis XI of the distortion-free protrusion 27a coincides with a rotation axis

[066] During engagement between the distortion-free protuberance 27a and the distortion groove 18a, the projecting tooth 27a1 on the distortion-free protuberance 27a is engaged with the drive force transmission part 18b to receive the rotary drive force, in such a way that the protuberance 27a is directed to rotate together with the groove 18a.

[067] During engagement between the projecting tooth 27a1 and the drive force transmission part 18b, the projection tooth 27a1 tends to deform due to the pressure of the groove 18a. As the projecting tooth 27a1 used to transmit the rotary driving force and the supporting disc 27a2 used to accurately position the protuberance 27a are arranged separately, the phenomenon that the supporting disc 27a2 may be affected by the projecting tooth 27a1 during rotation of the distortion-free bulge 27a can be avoided and therefore more accurate positioning of the bulge 27a can be realized and consequently unstable operation of the distortion-free bulge 27a when fitted with the distortion groove 18a can be avoided.

[068] In order for the protuberance 27a to be more easily interposed in the groove 18a, the projecting tooth 27a1 and the support disc 27a2 over the protuberance 27a may be conical. As illustrated in Fig. 10b, a protuberant upper surface 27a3 (as shown by the dashed line in the figure) is flat, in a position that is farthest from the center of the photosensitive cylinder, about the cylinder axis 27 (i.e., when the protuberance 27a is interposed in the groove 18a, the upper surface 27a3 is the first to enter the groove 18a) and a protuberance engaging surface 27a4 (as shown by the solid line in the figure) is a cross section, which is tangent to three ends of groove 18a, over protuberance 27a. As shown in the figure, the dimension of the upper surface 27a3 is smaller than that of the fitting surface 27a4. When the distortion-free protrusion 27a engages with the distortion groove 18a, therefore, the upper surface 27a3 can be interposed more easily into the groove 18a. As the protrusion 27a is conical, after the upper surface 27a3 is interposed into the groove 18a, other cross sections of the protuberance 27a penetrate deeply into the groove 18a until the mating surface 27a4 is tangent to the groove 18a. At this point, the rotation axis XI of the distortion-free protuberance 27a and the rotation axis X2 of the distortion groove 18a are coincident with each other.

[069] As illustrated in Fig. 10b, as the groove 18a is distorted, an upper surface of groove 18a1 (as shown by the solid line in the figure) does not coincide with a lower surface of the groove 18a2 (as shown by the dashed line in the figure) . In order to ensure large depth of the distortion-free protrusion 27a in the distortion groove 18a, the width of the protruding tooth 27a1 over the protrusion 27a must be set within a certain range. In order for the undistorted protuberance 27a to penetrate deeply into the distortion groove 18a, the width of the projecting tooth 28a1 must be less than or equal to the width of an overlapping area of the upper surface of the groove 18a1 and the lower surface of the groove 18a2 and thus , the projecting tooth 27a1 can be interposed more easily in the groove 18a and the maximum fitting area of the projecting tooth 27a1 and the groove 18a can be achieved. As the width of the projecting tooth 28a1 is smaller than that of the upper surface of the groove 18a1, the projecting tooth 27a1 can be fitted more conveniently with the upper surface of the groove 18a1 and, in this way, the projecting tooth 27a1 can be interposed more easily into slot 18a.

[070] The support disc in the embodiment adopts a circular structure. It is evident to those skilled in the art that the disc with the circular structure can be manufactured more easily and the need for manufacturing precision can be more easily met. After manufacturing the circular disc by means of industrial tools such as a turning machine, a key path is arranged on the circular disc by means of tools such as a grinding machine, general flat keys or keyways and the like that meet the needs dimensions are arranged in the key path and then the protuberance in the realization can be fabricated.

Achievement 2:

[071] As illustrated in Fig. 11, in order to increase the contact area of a projecting tooth 27a1' and a groove 18a and reduce the phenomenon of deformation of the projection tooth 27a1' due to excessive partial pressure, the section, which makes contact with one end of the groove 18a on the projecting tooth 27a1', is defined as a chamfer and the oblique position of the chamfer is basically the same as that of the end of the groove.

Achievement 3:

[072] As illustrated in Fig. 12a, a groove 18a' is a regular quadrilateral and a support disc 27a2 is fitted with four ends of the groove 18a', so as to ensure that the centers of a protuberance 27a and the groove 18a ' are coincident with each other. Furthermore, a projecting tooth 27a1 is engaged with one end of the groove in the groove 18a' and the driving force is transmitted through the groove 18a'.

[073] As illustrated in Fig. 12b, a groove 18a" is a regular pentagon and the support disk 27a2 is fitted with five ends of the groove 18a". Furthermore, the projecting tooth 27a1 is engaged with one end of the groove in the groove 18a" and the driving force is transmitted through the groove 18a'.

[074] It can be seen from the above that protrusions with the same structure can be applied to grooves with different shapes.

Achievement 4:

[075] As illustrated in Figs. 13a and 13b, compared to embodiment 1, an undistorted bulge 37a (as shown by the solid line in the figure) varies in shape compared to the bulge 27a (as shown by the dashed line in the figure) in embodiment 1.

[076] Fig. 13a is a cross-sectional diagram illustrating the state in which the distortion-free protuberance 37a is engaged with a distortion groove 18a. The undistorted protrusion 37a comprises two protruding columns and a supporting disc 37a2, wherein a first protruding column is a projecting tooth 37a1 and a second protruding column is a supporting column 37a3. In the embodiment, the support disk 37a2 and the support column 37a3 are taken as a mechanism for limiting the position of the drive force transmission mechanism. When the distortion-free protuberance 37a is fitted into the distortion groove 18a, the support disk 37a2 is fitted with two ends of the distortion groove 18a and another end of the distortion groove 18a is fitted with the support column 37a3. When the support disk 37a2 and the support column 37a3 are fitted with the ends of the distortion groove 18a, the coincidence of a rotation axis XI of the undistorted protuberance 27a and a rotation axis X2 of the distortion groove can be ensured. 18a and therefore stable transmission can be realized between the distortion-free protuberance 37a and the distortion groove 18a.

[077] The projecting tooth 37a1 is fitted with any drive force transmission component 18b over the groove 18a in such a way that the rotary drive force over the groove 18a can be transmitted to the protuberance 37a and thus the protrusion 37a can be directed to rotate together with the groove 27a.

[078] The support disk 37a2 is circular. X3 designates the center of the circle of the support disc 37a2 and the support column 37a3 and the projecting tooth 37a1 are arranged symmetrically with respect to the center X3. Furthermore, the distance between the apex of the supporting column 37a3 and the supporting disk 37a2 is equal to that between the apex of the projecting tooth 37a1 and the supporting disk 37a2 (i.e., the height is equal to each other) and the width of the supporting column 37a3 is the same as that of the projecting tooth 37a1.

[079] Similar to embodiment 1, the protuberance 37a may be conical, such that the protuberance 37a can be more easily interposed into the groove 18a during operation.

[080] As illustrated in Fig. 13b, the distortion groove 18a has an upper groove surface 18a1 and a lower groove surface 18a2. In order for the undistorted protuberance 37a to be interposed on the lower surface 18a2 of the groove 18a and to fit more easily in width, the width of the projecting tooth 37a1, the support disk 37a2 and the support column 37a3 over the protuberance 37a must be smaller or equal to the width of an overlapping area of the upper surface of the groove 18a1 and the lower surface of the groove 18a2.

[081] Compared to embodiment 1, the contact area of the support column 37a3 and the end of the groove 18a is larger, such that the protuberance 37a can be fitted more firmly with the groove 18a and therefore can be realized more stable transmission.

[082] The protuberance manufacturing process may be as follows: first, the circular support disc 37a2 is manufactured with tools such as a turning machine; and secondly, two key paths are arranged symmetrically on the disk and flat keys are correspondingly arranged on corresponding key paths to form the supporting column and the projecting disk. In this way, the protuberance manufacturing process is simpler and the need for precision can be met more easily.

[083] Other construction features or technical effects that are identical to those of embodiment 1 (the protuberance, for example, is defined as being conical; the protuberance can be fitted with grooves of different shapes) will not be repeated.

Achievement 5:

[084] Fig. 14a is the fifth embodiment of the present invention. In realization, the undistorted protrusion has a quadrangular shape. As illustrated in Fig. 14a, the undistorted bulge 47a is a quadrilateral, with a regular quadrilateral as an example in the embodiment. The regular quadrangular protuberance 47a has four vertices, wherein two vertices are engaged with two ends of a distortion groove 18a and are support vertices 47a2; another vertex 47a1 is engaged with another end of the groove 18a and is a tension vertex; and the two support vertices 47a2 and the tension vertex 47a1 are disposed, respectively, on two sides of a rotation axis X2 of the distortion groove 18a, respectively.

[085] It is evident to those skilled in the art that any one of the four vertices on the regular quadrilateral bulge 47a can be considered the tension vertex 47a1 and any other two vertices with respect to the vertex can be considered support vertices 47a2.

Achievement 6:

[086] Fig. 14b is the sixth embodiment of the present invention. In realization, a distortion-free protuberance has a pentagonal shape. As illustrated in Fig. 14b, the distortion-free protuberance 57a is a pentagon, with a regular pentagon as an example in the embodiment. Two support vertices 57a2 on the regular pentagonal protrusion 57a are fitted with two ends of a groove 18a and have the function of supporting and positioning the protrusion 57a and another tension vertex 57a1 is fitted with another end of the groove 18a, receiving the force of drive from the groove 18a and transmits the drive force to the protuberance 57a.

[087] It is evident to those skilled in the art that any two vertices of the pentagon can be considered support vertices 57a2 and another vertex can be considered support vertex 57a1.

Achievement 7:

[088] As illustrated in Figs. 15 and 16, a distortion groove 28a is disposed on a driving member of the image forming apparatus 28 and a supporting protuberance 28a2 is disposed in the middle of the distortion groove 28a and may be conical.

[089] A photosensitive cylinder drive member is disposed at one end of a photosensitive cylinder 7 and comprises a cylinder axis 27, wherein a distortion-free protuberance 27b is disposed on the cylinder axis 27 and has a projecting tooth 27b1 , a disc 27b2 and a support hole 27b3, whose center coincides with a rotation axis XI of the photosensitive cylinder.

[090] In the embodiment, the support protuberance 28a2 and the support hole 27b3 are taken as a mechanism for limiting the position of the drive force transmission mechanism.

[091] Fig. 17a is a cross-sectional diagram illustrating the state in which the distortion-free protuberance 27b is fitted into the distortion groove 28a. When the distortion-free protrusion 27b is fitted with the distortion groove 28a, the support hole 27b3 is engaged with the support protuberance 28a2 and has the function of supporting and positioning the protuberance 27b, in such a way that the axis of rotation XI of the distortion-free protuberance 27b can coincide with a rotation axis 28a. As illustrated in Fig. 17a, when the distortion-free protuberance 27b is fitted into the distortion groove 28a, the disc 27b2 is not engaged with ends of the groove 28a.

[092] The projecting tooth 27b1 receives the rotation driving force from the groove 28a when it is engaged with an end of the groove, in such a way that the protuberance 27b can be directed to rotate.

[093] In order for the support protrusion 28a2 to be more conveniently interposed in the support disc 27b3, the support hole 27b3 can be conical and the taper of the support hole 27b3 is basically the same as the support protuberance 28a2.

[094] Other construction features or technical effects that are identical to those of embodiment 1 (the protuberance, for example, is defined as being conical; the protuberance can be fitted with grooves of different shapes) will not be repeated.

[095] Figs. 17b and 17c are, respectively, the second solution and the third solution of the realization. The difference between the two solutions and the above solution according to the realization is as follows: the protuberance varies in shape.

[096] As illustrated in Fig. 17b, a symmetrical column 37b4 is disposed on a protuberance 37b and a projecting tooth 37b1 and the symmetrical column 37b4 are disposed with respect to a support hole 37b3 which is engaged with a support protuberance 28a2 over a groove 28a and has the function of supporting and positioning the protrusion 37b.

[097] As illustrated in Fig. 17c, a bulge 47b is a regular quadrilateral, wherein a vertex of the regular quadrangular bulge 47b is a tension vertex 47b1 and the bulge also has a support hole 47b3 that is engaged with a bulge of support 28a2 over a groove and has the function of supporting and positioning the protrusion 47b. Naturally, the protuberance can also have a pentagonal and similar shape.

Achievement 8:

[098] A driving member of the imaging apparatus in the embodiment is identical to that of embodiment 1 and will not be repeated.

[099] Fig. 18 is a stereogram of a photosensitive cylinder drive member in embodiment 8. As illustrated in the figure, the photosensitive cylinder drive member comprises a cylinder flank 2, a cylinder axis 3 and a protuberance without distortion 4, in which the cylinder flank 2 is disposed on the end of a photosensitive cylinder 1, connected to the photosensitive cylinder 1 and used to transmit the received drive force to the photosensitive cylinder 1; the axis of the cylinder 3 extends axially from the end part of the cylinder flank 2 and is used to rotatably support the photosensitive cylinder 1 during the operation of a process cartridge; the distortion-free protrusion 4 extends axially from the rear face of the cylinder shaft and is used to receive the driving force of the driving member of the image forming apparatus 18; and a support disc 4b is disposed on the undistorted protuberance 4 and has a first projecting tooth 5a which extends along the radial direction of the undistorted protuberance 4 and is disposed obliquely on the support disc 4b of the undistorted protuberance 4. distortion 4.

[0100] In this embodiment, the first projecting tooth 5a and the support disc 4b are taken, respectively, as the tensioning mechanism and the mechanism for limiting the position of the drive force transmission mechanism.

[0101] During transmission of the drive force, the first projecting tooth 5a on the distortion-free protuberance 4 of the photosensitive cylinder drive member is engaged with any drive force transmission component 18b to transmit the drive force; the support disc 4b of the undistorted protuberance of the photosensitive cylinder drive member is tangent to the three ends of a groove of the drive member of the image forming apparatus and engaged with them at three tangent points PI, P2 and P3, so that the photosensitive cylinder drive member and the image forming apparatus drive member 18 can be centralized during transmission of the drive force.

[0102] Fig. 19 is a force diagram illustrating the assembly of the photosensitive cylinder drive member and the image forming apparatus drive member. In the figure, "A" designates the direction of rotation of the driving member of the image forming apparatus; FI 1 designates the force applied to the first tooth in projection 5a by the driving member of the imaging apparatus and is resolved into a normal force FI 2 and a radial force F14; FI 5 designates the force generated by the driving member of the imaging apparatus at the tangent point PI; FI 3 designates the force generated by the driving member of the imaging apparatus at the tangent point P2; and no force is applied to P3. In summary, the following force formula is obtained: with the following results: F13 = 2.F14 and This means that the force is applied to the driving member of the imaging apparatus or the photosensitive cylinder driving member at P1 and the force 2.F14 is applied to the driving member of the imaging apparatus or the photosensitive cylinder driving member at P2 .

[0103] The drive member of the photosensitive cylinder and the drive member of the imaging apparatus wear each other out during engagement and transmission of drive force. In the solution, therefore, the photosensitive cylinder driving member is taken as the projecting tooth of the driving force transmission component and arranged in different positions with the distortion-free protuberance supporting disc, which has the positioning function, of in such a way that the drive force transmission function and the positioning function cannot be affected by wear.

Achievement 9:

[0104] Figs. 20 and 21 are, respectively, a stereogram and a front view of a photosensitive cylinder drive member in the embodiment and Fig. 22 is a top view illustrating the assembly of the photosensitive cylinder drive member and a drive member of the apparatus. of image formation in the making. The driving member of the image forming apparatus illustrated in embodiment adopts the driving member of the image forming apparatus illustrated in embodiment 1 and will not be repeated. As illustrated in the figures, the photosensitive cylinder driving member comprises a cylinder flank 2, a cylinder axis 3 and a cylindrical distortion-free protuberance 4, wherein the cylinder flank 2 is fixedly connected to the end of a photosensitive cylinder. - sible 1; the axis of the cylinder 3 extends axially from the end part of the cylinder flank 2 and is used to rotatably support the photosensitive cylinder 1 during operation of a process cartridge; the cylindrical distortion-free protuberance 4 extends axially from the rear face of the cylinder shaft 3 and is used to receive the driving force of the driving member of the image forming apparatus 18; and a pair of projecting teeth 4a extending along the radial direction of the undistorted protuberance 4 and engaged, respectively, with any two drive force transmitting parts on the drive member of the image forming apparatus disposed on a disk support plate 4b of the undistorted protuberance 4. Furthermore, the projecting teeth 4a are arranged obliquely on the support disc 4b of the undistorted protuberance 4. In the implementation, the projecting teeth 4a and the support disc are taken, respectively, as the tensioning mechanism and the position limiting mechanism of the drive force transmission mechanism. The standard angle of alpha minimum included angle between the two teeth in 4a projection is 120°, with the upper limit tolerance of the angle generally up to 2°. The theta manufacturing accuracy error is allowable for teeth in 4a projection in the solution and is 2° to 10°, preferably 2° to 4°. If theta designates the angle error, the minimum included angle alpha between the two teeth in 4a projection is alpha + theta. At this point, the two projecting teeth 4a may not be engaged with the drive force transmission part 18b of a groove 18a and the projecting tooth disposed on the upper end in the flow direction of rotation is the first to be engaged with the driving force transmission component on the driving member of the image forming apparatus and has the function of buffering. If the 4a projection tooth has the theta manufacturing error below in the flow direction of rotation, the projection tooth may have a graduated fitting surface due to theta, which has the function of buffering during the fit between the 4a projection tooth and the drive force transmission component 18b of the groove, such that the damage between the drive member of the imaging apparatus and the photosensitive cylinder drive member can be reduced. Cylindrical surfaces between the two teeth in projection 4a of the distortion-free protuberance make contact with ends of the drive member of the image forming apparatus, in such a way that positioning of the drive member of the photosensitive cylinder can be carried out. In addition, fillets are also arranged in the connection positions of the teeth in projection 4a and the cylindrical surfaces of the protuberance without distortion, in order to reduce the stress concentration. Furthermore, the cylinder flank 3, the cylinder axis 3, the cylindrical distortion-free protuberance 4 and the projecting teeth 4a on the photosensitive cylinder drive member may be integrally molded by the same materials and may also have plug structures. Furthermore, a cylinder gear 2a used to transmit driving force to other elements (such as a developing element) can also be arranged on the cylinder flank 2.

[0105] Fig. 23 is an assembly diagram of the photosensitive cylinder drive member and the image forming apparatus drive member and Fig. 24 is a cross-sectional force diagram illustrating the state after fitting between the driving member of the imaging apparatus and the photosensitive cylinder driving member. As illustrated in the figures, the photosensitive cylinder driving member is tangent and engaged with the groove ends of the imaging apparatus driving member at three tangent points P4, P5 and P6; "A" designates the direction of rotation of the driving member of the image forming apparatus; and the force F24 and the force F56 which are identical to each other are applied to the photosensitive cylinder drive member by the image forming apparatus drive member. If the torsional moment of the photosensitive cylinder driving member is twice that of embodiment 8, F24 and F56 are identical to FI 1 in embodiment 8; F24 is resolved into a normal force F2 and a radial force F4; F56 is resolved into a normal force F5 and a radial force F6; F2 and F5 are identical to FI 2 in realization 8; and F4 and F6 are identical to F14 in embodiment 8. Supposing FI designates the force generated by the driving member of the image forming apparatus at the tangent point P5, F3 designates the force generated by the driving member of the imaging apparatus at the tangent point P6 and no force is applied to P4, in summary, the following force formula can be obtained: with the following results: F1=2.F4 and F3=0. This means that the force 2.F4 is applied to the drive member of the image forming apparatus of the photosensitive cylinder drive member at P5 and no force is applied to P6. Compared to embodiment 8, the number of stress points in the solution is reduced, such that wear of the driving member of the image forming apparatus and the photosensitive cylinder driving member at the tangent points P5 and P6 can be reduced. reduced and, in this way, the positioning stability of the photosensitive cylinder drive member can be improved and, consequently, more stable drive force transmission can be realized.

Achievement 10:

[0106] It is evident to those skilled in the art that one projecting tooth among the two projecting teeth is defined so that it is an oblique tooth and the other projecting tooth is defined so that it is a straight tooth, also achieving the same technical effect . Fig. 25 is a stereogram of a photosensitive cylinder drive member in the embodiment. As illustrated in the figure, the oblique tooth 4a is disposed obliquely on a supporting disc 4b of an undistorted protuberance and the straight tooth 4c is arranged vertically on the supporting disc 4b.

Achievement 11:

[0107] When the rotational speed of an imaging apparatus is lower, the torsional force of a driving member of the imaging apparatus is smaller and two projecting teeth of a photosensitive cylinder driving member may both defined as straight teeth. Fig. 26 is a stereogram of a photosensitive cylinder drive member in the embodiment, wherein 4d indicates the projecting teeth of the photosensitive cylinder drive member. The manufacturing accuracy of the photosensitive cylinder drive member can therefore be further reduced.

[0108] In the present invention, with respect to the projecting tooth(s) 30 illustrated in embodiments 8 to 11, with embodiment 9 as an example: as illustrated in Figs. 21 and 22, the beta angle included between the projecting teeth 4a and the axis of rotation of the photosensitive cylinder drive member is 3° to 40°, preferably 25° to 30° such that the disengagement phenomenon of the photosensitive cylinder driving member of the image forming apparatus driving member during transmission of the driving force can be avoided when smooth engagement between the photosensitive cylinder driving member and the forming apparatus driving member can be ensured of images, and in this way, stable driving force transmission can be realized between the driving member of the imaging apparatus and the driving member of the photosensitive cylinder. Furthermore, LI designates the length of the protruding teeth 4a from the supporting disc 4b along the radial direction and is 2 to 5 mm, preferably 2.3 to 3.3 mm, in order to ensure that the member of the photosensitive cylinder has a moment of force sufficient to direct the transmission of force.

[0109] In the present invention, with respect to the projecting tooth(s) in the above embodiments, with embodiment 9 as an example: as illustrated in Figs. 21, 22 and 27, the projecting teeth 4a also have engaging surfaces 4a1, the area of which is 5 to 20 mm 2, preferably 7 to 16 mm 2. During the transmission of drive force, the engaging surfaces 4a1 are engaged with inner walls of the driving force transmitting part of the driving member of the image forming apparatus to transmit the driving force. As the engaging surfaces 4a1 are disposed on the projecting teeth 4a, wear between the driving member of the photosensitive cylinder and the driving member of the imaging apparatus can be reduced. In addition, each projecting tooth also has a vertex angle 4a2 and two parallel planes 4a3 that are connected to the supporting discs of the projecting teeth, where beta designates the angle included between planes 4a2 and 4a3 and the axis of the photosensitive cylinder . In addition, each mating surface also has straight ends s1 and s2 and a chamfer end s3, wherein the straight ends s1 and s2 are parallel to each other; the angle phi included between the chamfer end s3 and the photosensitive cylinder axis is 5° to 50° and, preferably, 10° to 40°; and the gamma angle included between the straight end s1 and a connecting line from the center of the photosensitive cylinder drive member to the apex angle 4a2 of the projecting tooth is from 0° to 90° and preferably from 25° to 45° °. As illustrated in Figs. 27 to 29, direction "B" as illustrated in Fig. 27 is parallel to the direction of radial extension of the projecting teeth.

[0110] It is evident to those skilled in the art that three teeth in symmetrical projection can also be defined and are all teeth in oblique projection or teeth in vertical projection. Otherwise, one is defined as an obliquely projected tooth and the other two are defined as vertically projected teeth, or one is defined as a vertically projected tooth and the other two are defined as obliquely projected teeth and can also be achieved the same technical effect. The tooth in oblique projection indicates that the tooth in projection is arranged obliquely on the disc supporting the protuberance without distortion and the tooth in vertical projection indicates that the tooth in projection is arranged vertically on the disc supporting the protuberance without distortion.

[0111] It is evident to those skilled in the art that the undistorted bulge support disk and a cylindrical surface of the undistorted bulge are the same component.

[0112] The present invention relates to a process cartridge, which comprises a photosensitive cylinder and also comprises the drive force transmission mechanism according to any of the claims, wherein the drive force transmission mechanism is arranged over the end of the photosensitive cylinder.

Claims (15)

1. Mechanism for transmitting drive force, comprising: a photosensitive cylinder drive member (7), wherein the photosensitive cylinder drive member (7) is engaged with an image forming apparatus drive member (18 , 28) to transmit the driving force; wherein the photosensitive cylinder drive member (7) comprises a distortion-free protuberance (27a, 37a, 47a, 57a, 27b, 37b1) extending axially from the end face of a cylinder shaft (27) and is fitted with the groove over the image forming apparatus driving member (18, 28); wherein the protuberance (37b, 47b) comprises a position limiting mechanism and a tensioning mechanism; wherein the position limiting mechanism and the tensioning mechanism are arranged in different positions; wherein the tensioned mechanism comprises two or more projecting teeth (27a1, 28a1, 37a1, 27b1, 5a, 4a) arranged obliquely on the undistorted protuberance (27a, 37a, 47a, 57a, 27b, 37b1) taken as a mechanism tensioned; wherein the position limiting mechanism comprises a support disc disposed on the protuberance and engaged with edges of the groove; and wherein each of the projecting teeth (27a1, 28a1, 37a1, 27b1, 5a, 4a) further comprises a respective coupling surface engaged with the drive force transmission part (18b) to transmit the drive force; wherein each of the projecting teeth (27a1, 28a1, 37a1, 27b1, 5a, 4a) further comprises two parallel planes which are connected to the support disc, and wherein the coupling surface is at an angle included with the two parallel planes; and the mechanism for transmitting drive force being CHARACTERIZED by the fact that the image forming apparatus comprises: a triangular groove (18a) having a triangular cross-section and a drive force transmission part (18b) disposed in three apex angles (57a1, 47a1, 47b1) of the triangular groove with a triangular cross section. 2. Drive force transmission mechanism according to claim 1, CHARACTERIZED by the fact that when the number of projecting teeth is exactly two, the two projecting teeth are respectively engaged with two of the three parts of drive force transmission arranged at the three apex angles of the groove. 3. Drive force transmission mechanism according to claim 1 or 2, CHARACTERIZED by the fact that the angle included between the projecting teeth and an axis of rotation of the photosensitive cylinder drive member is 3° to 40°. 4. Drive force transmission mechanism according to claim 3, CHARACTERIZED by the fact that the angle included between the teeth in oblique projection and the axis of rotation of the photosensitive cylinder drive member is 25 °to 30°. 5. Drive force transmission mechanism, according to claim 1 or 2, CHARACTERIZED by the fact that the length of each protruding tooth starting from the protuberance support disc without distortion along the radial direction is 2 to 5 mm. 6. Drive force transmission mechanism according to claim 5, CHARACTERIZED by the fact that the length of each protruding tooth starting from the protuberance support disc without distortion along the radial direction is 2.3 to 3.3 mm. 7. Drive force transmission mechanism, according to claim 2, CHARACTERIZED by the fact that the minimum included angle between the two projecting teeth is 120° and the upper limit tolerance of manufacturing accuracy of the included angle is 2° to 10°. 8. Drive force transmission mechanism, according to claim 7, CHARACTERIZED by the fact that the upper limit tolerance of manufacturing precision of the angle included is 2° to 4°. 9. Drive force transmission mechanism according to claim 1 or 2, CHARACTERIZED by the fact that the angle included between the chamfered edges of the coupling surfaces and a photosensitive cylinder axis is 5° to 50° . 10. Drive force transmission mechanism, according to claim 9, CHARACTERIZED by the fact that the angle included between the chamfered edges of the coupling surfaces and the photosensitive cylinder axis is 10° to 40°. 11. Drive force transmission mechanism, according to claim 1 or 2, CHARACTERIZED by the fact that each coupling surface has two straight edges and the angle included between the straight edge and a connection line from the center of the photosensitive cylinder drive member to an apex angle of each projecting tooth is 0° to 90°. 12. Drive force transmission mechanism according to claim 11, CHARACTERIZED by the fact that the angle included between the straight edge and the center connection line of the photosensitive cylinder drive member and the apex angle of each tooth in projection is 25° to 45°. 13. Drive force transmission mechanism, according to claim 1 or 2, CHARACTERIZED by the fact that the coupling surface area is 5 to 20 mm2. 14. Drive force transmission mechanism, according to claim 13, CHARACTERIZED by the fact that the coupling surface area is 7 to 16 mm2. 15. Process cartridge, comprising a photosensitive cylinder, CA-RACTERIZED by the fact that the process cartridge further comprises the drive force transmission mechanism as defined in any one of claims 1 to 14, the drive force transmission mechanism driving force is arranged at the end of the photosensitive cylinder.