Abstract:
To provide a flange to be attached to an end of a photoconductor drum, the flange including: a drum engagement part capable of being engaged with an inner surface of the photoconductor drum; and a center hole, wherein the flange is prepared by cutting at least one of a surface of the engagement part and an inner surface of the center hole so that the axis of the center hole coincides with the axis of the photoconductor drum.

Description:
BACKGROUND OF THE INVENTION 
   1. Field of the Invention 
   The present invention relates to a flange used for a base support (drum) of an electrophotographic photoconductor and, more particularly, to a flange made of synthetic resin, a flange processing device, and a method for processing a flange. 
   2. Description of the Related Art 
   In the electrophotographic photoconductor field for electrostatic image processing in electrostatic copiers, electrostatic printers, facsimiles, etc., a photoconductor drum is generally provided with a photosensitive layer at the uppermost surface and equipped with flanges in the openings formed at either ends of the photoconductor drum, and various types of units are arranged around it. While the photoconductor drum rotates, these units perform necessary or desired processes (e.g., selective exposure, development, image transfer, charge removal, and cleaning) on the photoconductor layer. 
   An electrophotographic photoconductor is fabricated by assembling together a cylindrical drum base support with a photosensitive layer that has been processed to a desired surface condition and centered flange members, i.e., the drum base support and flange members are separately manufactured and then assembled into a photoconductor. 
   As shown for instance in  FIG. 14 , a flange member  10  made of synthetic resin or the like includes a flange part (or drum bumping part)  2  and an insertion part (or drum engagement part)  1  to be inserted into the inside of a cylindrical photoconductor drum (base support)  20 . The insertion part  1  protruding toward the movable side B is fitted to the inner side of the photoconductor drum  20  and serves to firmly fix the flange member  10  to the photoconductor drum  20 , and the flange part  2  serves to fix the positional relationship between the photoconductor drum  20  and flange member  10  by being bumped into the edge of the photoconductor drum  10 . The outer surface of the flange part  2  is provided with a helical gear  3  (hereinafter simply referred to as a “gear part” in some cases) that is engaged with a drive gear (not shown) for transmitting rotational power to the helical gear  3 . In addition, a shaft hole  4  is formed at the axial center of the flange member  10  so that the flange member is rotatively supported from the fixed side A. P/L denotes a reference plane.  FIG. 15  is a cross-section of an example of a gear-equipped flange member of different shape, cut along a plane passing through its central axis. This flange member  10  has a protruding helical gear  3  at the fixed side A of a thin flange part  2 , which the helical gear  3  is smaller in diameter than the flange part  2 . A concentric shaft hole  4  is formed penetrating through the insertion part (drum engagement part)  1 , flange part  2 , and helical gear  3 . 
   In a case where a flange member to be pressed into a photoconductor drum is made of resin, in the prior art, the flange member is provided with an insertion part (drum engagement part) and an insertion stopping part (e.g., a flange part at which the flange member is bumped into the drum). The shape of the flange member needs to be so designed that the area of the flange member contacting the drum is large enough to avoid the situation where only the flange member rotates when force has been applied for rotating the photoconductor drum. Accordingly, the outer surface of the drum engagement part of the flange member, contacting the photoconductor drum, is designed to conform to the surface of the photoconductor drum. 
   Flanges of this type for photoconductor drum are disclosed for instance in Japanese Patent Application Laid-Open (JP-A) Nos. 07-13468 and 10-319782. Moreover, electrophotographic photoconductors formed using flanges are disclosed for instance in JP-A Nos. 2003-233271, 2003-241573, 2003-255759 and 2004-184452. 
   An image forming apparatus is generally equipped with a development device for supplying a toner-containing developer to the photoconductor drum, or a latent image bearing member, in order to visualize a latent image on the drum. Such development device systems are widely used wherein a development roller carries brush-shaped toner-containing developer particles on its surface, which are then allowed to contact a latent image on the photoconductor for visualizing the latent image. 
   Meanwhile, for example, in a case of a magnetic developer, a known configuration of a development roller that carries brush-shaped developer particles on its surface is that multiple magnets that serve as main magnetic poles and transfer magnetic poles are arranged in the development roller, whereby developer particles that have been transferred on the roller surface by means of the transfer magnetic poles are agglomerated into sets of particles stacked on top of each other on the roller surface by the main magnetic poles, making them in contact with the photoconductor surface. 
   Because the height of the stack of the particles attached to the development roller is influenced by magnetic attraction, the distance between the development roller and the photoconductor, i.e., the so-called development gap, needs to be specified for optimized conditions in which the developer is supplied to and is in contact with the photoconductor surface (see for example JP-A No. 2004-184452 for more details in this regard). 
   Support and rotation of the photoconductor drum are generally provided by a rotation spindle or bearings that are provided to flanges attached to both ends of the photoconductor drum, or by power supplied via gears. For this reason, these flanges need to be precisely and firmly fitted into openings at both ends of the photoconductor drum. For smooth and precise rotation of the photoconductor drum, the centers of the flanges need to be constantly held at the axis of rotation. 
   In order to obtain high-resolution images in an electrophotographic apparatus equipped with a photoconductor by optimizing the foregoing conditions by specifying the development distance, it is effective to manufacture a high-precision photoconductor. More specifically, it is necessary to reduce radial run-out of the photoconductor drum with respect to the flanges attached to both ends of the drum. To achieve this, it is necessary to use high-precision flanges. 
   However, attachment of flanges to a photoconductor is often conducted by press-fitting in combination with an additive where necessary, and thus the concentricity of the center holes of the flanges relative to the photoconductor drum surface is dependent on the manner in which they were press-fitted into the photoconductor. In this case, because of surface deviations of the press-fitted portions of the flange members from their center holes as well as of deformation of the flanges as a result of press-fitting, it has been difficult to improve concentricity of the flange center holes relative to the photoconductor drum surface. 
   Flanges formed by injection molding of plastic have been generally used as conventional flanges for photoconductor drum. However, there have been limitations with respect to precision in parameters of these flanges due to a variety of factors including dimensional precision of the mold used, deterioration of the mold, reproducibility of assembling the mold after disassembled for cleaning, lot-to-lot variations of resin, and molding variations. Specific characteristic values are concentricity and roundness. For continued mass production of flanges, however, there is a limitation in these values—it is required to admit a concentricity of 15 μm between the center shaft hole and drum engagement part of the flange and a roundness of 10 μm for both the shaft hole and drum engagement part. As described above, however, it is imperative to provide high-precision flanges for high-precision image formation. To achieve this, it is necessary that the molded article be subjected to a second cutting process to produce a high-precision component. Known technologies (methods and system) undesirably require a lot of skill and many steps for this. 
   Moreover, flanges for photoconductor drum are often equipped with a gear for transmitting driving force. In this case the mesh precision of the gear is an important characteristic value. Because of the structure of the mold, it has been difficult for flanges for photoconductor drum that are formed by injection molding to simultaneously exhibit high gear precision and high concentricity of the shaft hole relative to the drum engagement part diameter (see  FIG. 15 ). 
   SUMMARY OF THE INVENTION 
   The present invention has been accomplished in order to overcome the foregoing problems, and an object of the present invention is to provide a flange with significantly improved run-out over its length that is used for a photoconductor drum, as compared to those prepared by injection molding through a conventional mold. Another object of the present invention is to provide a flange processing device and a method for processing a flange, each of which is capable of providing flanges of the same quality by making both the concentricity and roundness 0.005 mm or less. The final object of the present invention is to enable image forming apparatus to produce high-quality images. 
   The present invention aims to significantly increase dimensional precision of a synthetic resin flange by cutting two important portions thereof through a cutting process, which such a high dimensional precision has not been achieved only by injection molding. The flange of the present invention to be attached to a photoconductor drum includes a drum engagement part capable of being engaged with an inner surface of the photoconductor drum; and a center hole, wherein the flange is prepared by cutting at least one of a surface of the drum engagement part and an inner surface of the center hole so that the axis of the center hole coincides with the axis of the photoconductor drum. Cutting of this flange is performed without entailing re-clamping of the flange to a lathe chuck, and thereby the drum engagement part and the center hole are cut in such a way that the concentricity between the drum engagement part and the center hole is 0.005 mm or less and that the roundness of the drum engagement part is 0.005 mm or less, thereby reducing variations in the development gap and providing high-quality images. 
   It is preferable to form a narrow groove near the drum bumping part (flange part) so that the outer diameter of the drum engagement part (engagement diameter) is 0.1-0.5 mm smaller at the groove than at other areas of the drum engagement part. To prevent burrs on the flange from being pinched between the flange and the drum, the groove is provided near the drum bumping part so that the burrs are placed into the groove, thereby the stabilizing engagement condition. This groove or step cannot be formed with high precision only by means of injection molding, but can be formed by cutting process. The groove provided near the drum bumping part allows the flange to be attached to a photoconductor drum without any pinching of burrs at the drum end. 
   Moreover, the flange may be provided with a protruding part at a position opposite to the drum engagement part, which the protruding part is to be clamped to a lathe chuck upon cutting of the drum engagement part and center hole. This protruding part is provided to a flange with no gears that allows clamping of the flange to a lathe chuck. Since this flange is provided with the protruding part at its end surface, it can be clamped to the chuck even without gears. Thus cutting of the drum engagement part and center hole is made possible without re-clamping of the flange clamped to the chuck. 
   The flange processing device of the present invention includes: stocking means capable of housing a plurality of flanges therein; cutting means for cutting the flanges; and supplying means for supplying the flanges housed in the stocking means to the cutting means. Thereby, the flanges are transferred to the cutting means automatically and thus the injection molding step can be efficiently connected to the cutting step. 
   A cooling unit may be provided for blowing cooled air to the stocking means. This cooling unit for blowing cooled air to the flanges to be transferred to the cutting means can facilitate shape stabilization and thereby the flanges can be subject to cutting step in a time efficient manner. 
   The flange processing device of the present invention is one in which a thread-like chipping is removed by air suction from the inside of the lathe chuck at the main spindle. With this configuration, it is possible to remove chipping generated as a result of cutting of center hole and to prevent the chipping from being entwined with the bite. 
   The method of the present invention for processing a flange is one for processing a flange which include a drum engagement part capable of being engaged with an inner surface of a photoconductor drum and a center hole and which is to be attached to an end of the photoconductor drum, wherein in a state where a flange provided with a gear part is clamped to a lathe chuck at the gear part, at least one of a surface of the drum engagement part and an inner surface of the center hole is cut. By cutting the drum engagement part (shaft hole) and center hole in a state where the gear part is clamped to the lathe chuck, it is possible to reduce the pitch error over total teeth (i.e., it is possible to improve gear precision). Upon cutting of a flange provided with a protruding part, cutting of the drum engagement part and center hole is performed with the protruding part being clamped to the lathe chuck. In this way the drum engagement part and center hole can be cut with high precision. In the foregoing flange processing method, it is preferable to adopt an air balloon chuck in order to clamp a flange to the lathe chuck with a low pressure. Alternatively, a diaphragm chuck may be used in order to clamp a flange with a low pressure just as the air balloon chuck can. In this case, similar effects can be obtained. More specifically, the use of such a diaphragm chuck enables flange clamping at a pressure low enough to avoid deformation of the flange. Furthermore, the number of jaws provided to the lathe chuck is preferably 6 to 8. This prevents flange deformation to a greater extent. 
   It is preferable during cutting process to remove a thread-like is chipping by air suction from the inside of the lathe chuck. In addition, it is preferable that the bite enter the flange at an angle of 3° to 45° for the cutting of the center hole. By doing so it is possible to prevent generation of burrs at the initial stage of cutting. It is also preferable that the bite withdraw out of the flange at an angle of 3° to 45° for the cutting of the center hole. By doing so it is possible to prevent generation of burrs at the final stage of cutting. Furthermore, it is preferable to set cutting depth to 0.05-3 mm. This allows chippings to be linked together into a thread-like chipping which can be readily removed. 
   In the flange processing method, during the cutting process, a feedback control is established in which the work temperature is measured and cutting depth is changed according to the linear expansion coefficient of resin used. By this feedback control mechanism, the processed flanges have the same dimension even when room temperature and the flange surface temperature varied during the cutting process. 
   According to the present invention, it is possible to manufacture a high-precision flange for photoconductor drum without fail, and to provide a high-quality photoconductor drum attached to a flange that has significantly improved run-out over its length as compared to those prepared by injection molding through a conventional mold. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  shows a schematic perspective view showing an appearance of a flange of the present invention prior to cutting process. 
       FIG. 2  is an enlarged cross-sectional view of the flange of  FIG. 1  after cutting process, which is provided with a groove at the bottom of the drum bumping part thereof. 
       FIG. 3  is a schematic perspective view showing an appearance of another flange of the present invention prior to cutting process. 
       FIG. 4  is a schematic perspective view showing an example of the shape (prior to cutting process) of a gear-free flange of the present invention, which is provided with a protruding part. 
       FIG. 5  is a perspective view showing a system configuration of a flange processing device (system) according to the present invention. 
       FIG. 6  is a schematic view showing a configuration for removing a thread-like chipping by air suction at the spindle of the lathe. 
       FIG. 7  is a schematic view showing an example of a device for uniformly blowing cooled air to a stacker. 
       FIG. 8  is a schematic diagram for explaining a pattern in which the bite moves upon cutting of the center shaft hole. 
       FIG. 9  is another schematic diagram for explaining a pattern in which the bite moves upon cutting of the center shaft hole. 
       FIG. 10  shows data obtained after cutting process. 
       FIG. 11  shows concentricity and roundness values for an article processed by a processing device according to an embodiment of the present invention, which are measured by a roundness analyzer made by TOKYO SEIMITSU. 
       FIG. 12  shows processing results obtained using diaphragm chucks other than a 6-jaw diaphragm chuck. 
       FIG. 13  shows variations in outer diameter of flange when room temperature varied from 22° C. to 27° C. 
       FIG. 14  is a cross-sectional view of an example of a gear-attached flange, including its center axis. 
       FIG. 15  is a cross-sectional view of another example of a gear-attached flange, including its center axis. 
   

   DESCRIPTION OF THE PREFERRED EMBODIMENTS 
   Hereinafter an embodiment of the present invention will be described with reference to the drawings.  FIG. 1  shows a schematic perspective view showing an appearance of a flange (member)  10 A of the present invention prior to cutting process.  FIG. 2  is an enlarged cross-sectional view of the flange  10 A of  FIG. 1  after cutting process, which is provided with a groove  7  at the bottom of the drum bumping part  2  thereof.  FIG. 3  is a schematic perspective view showing an appearance of another flange  10 B of the present invention prior to cutting process.  FIG. 4  is a schematic perspective view showing an example of the shape (prior to cutting process) of a gear-free flange  10 C of the present invention, which is provided with a protruding part  5   b .  FIG. 5  is a perspective view showing a system configuration of a flange processing device (system) according to the present invention. 
   A flange  10 A shown in  FIG. 1  is a two-staged substantially cylindrical member formed by injection molding of synthetic resin. The flange  10 A is cut on a lathe or the like to give a shape shown in  FIG. 2 . One end surface  5   a  of a large diameter-main cylinder  5  includes a protruding part  5   b  that after cutting serves as a drum engagement part  1  to be fitted into the inner circumference of a photoconductor drum end (not shown). At the center of the other end surface  5   c  of the main cylinder  5 , having a circular end, has a protruding helical gear  3  and protruding shaft cylinder  6  to be a shaft portion, both of which are smaller in diameter than the main cylinder  5 . The center hole  6   a  in the shaft cylinder  6  communicates with the shaft hole  4 . As shown in  FIG. 2 , the drum engagement part  1  is cut to have a predetermined outer diameter in such a way that it is coaxial with the helical gear  3 . As shown in the cross-sectional view of  FIG. 2 , a narrow groove  7  is formed in the vicinity of the drum bumping part (flange part)  2  of the flange  10 A so that the diameter of the drum engagement part  1  (engagement diameter) is 0.1-0.5 mm smaller at the groove  7  than at other areas of the drum engagement part  1 . The center hole part  6   a  of the cylindrical shaft portion  6  provided at the center of the flange is processed to form a shaft hole  4  that is coaxial with the drum engagement part  1  and helical gear  3 . 
   A flange  10 B shown in  FIG. 3  is also a substantially cylindrical member formed by injection molding of synthetic resin. The flange  10 B is cut on a lathe or the like to form a protruding part  5   b  at one end surface  5   a  of the main cylinder  5 , which the protruding part  5   b  becomes a drum engagement part  1  to be fitted into the inner circumference of a photoconductor drum end. In the flange  10 B shown in  FIG. 3 , the other end surface of the main cylinder  5  is processed to be a helical gear  3 . In a subsequent process, the drum engagement part  1  is cut so as to be coaxial with the helical gear  3 . A narrow groove (step)  7  is formed in the vicinity of the drum bumping part (flange part including the helical gear  3 )  2  of the flange  10 B so that the diameter of the drum engagement part  1  (engagement diameter) is 0.1-0.5 mm smaller at the groove  7  than at other areas of the drum engagement part  1 . The center hole part at the center of the flange is processed to form a shaft hole  4  that is coaxial with the drum engagement part  1  and helical gear  3 . 
   A flange  10 C of the present invention shown in  FIG. 4  (prior to cutting process) is a flange that does not have a gear, and is a member formed by injection molding of synthetic resin as are the foregoing flanges  10 A and  10 B. The flange  10 C is cut on a lathe or the like to form a protruding part  5   b  at one end surface  5   a  of the main cylinder  5 , which the protruding part  5   b  becomes a drum engagement part  1  to be fitted into the inner circumference of a photoconductor drum end. At the center of the other end surface  5   c  of the main cylinder  5 , there is provided a protruding protruding part  8  (for chucking) that is smaller in diameter than the main cylinder  5 , forming a two-staged substantially cylindrical member. At the inner side of the protruding part  8 , a protruding shaft cylinder  6  is formed that becomes a shaft portion. The center hole part of the cylindrical shaft portion  6  provided at the center of the flange is processed to form a shaft hole  4  that is coaxial with the drum engagement part  1  and helical gear  3 . The drum engagement part  1  is cut to have a predetermined outer diameter and, as in the case of  FIG. 2 , in the vicinity of the drum bumping part (flange part)  2  thereof, there is provided a narrow groove  7  so that the diameter of the drum engagement part  1  (engagement diameter) is 0.1-0.5 mm smaller at the groove  7  than at other areas of the drum engagement part  1 . 
   Because of their specific structures these flanges  10 A,  10 B and  10 C can achieve the concentricity of 0.005 mm or less and roundness of 0.005 mm or less much easier than conventional flanges. This is achieved by setting the inner and outer diameters of the drum engagement part and center hole to predetermined values through a cutting process in which the flange is clamped to the lathe chuck only once (i.e., without re-clamping the flange to the chuck). 
   In particular, the use of a processing device to be described later and a cutting process in accordance with a processing method to be described later can, without fail, ensure that both the concentricity and roundness are 0.005 mm or less without re-clamping of the flange to be processed. 
   A flange processing device (system) shown in  FIG. 5 , which is suitable for cutting of the flanges, will be described below. The flange processing device  100  shown in  FIG. 5  is composed primarily of a lathe  50 , a cutting machine to be described later in detail. A stacker  70  can be attached to the flange processing device  100  for increasing overall operational efficiency in conjunction with an injection molding machine  60 . To be more specific, a stacker  70  for transferring flanges is attached to the flange processing device  100  so that flanges formed by injection molding can be readily supplied to the cutting machine. The stacker  70  is provided with trays  71  for storing flanges prepared using the injection molding machine  60 , and is connected to the side of the lathe  50  (hereinafter may be referred to as a “cutting machine”). In this way flanges can be automatically supplied from the tray  71  to the chuck  51  of the cutting machine  50  by means of a (flange member) supplier  72 . 
   An air blower  80  is incorporated into the flange processing system  100  so that the stacker  70  can function effectively. Injection molded flanges exhibit shrinkage right after their preparation and thus generally need to be left stand for a long period of time before their shapes are stabilized. However, it is necessary that full shrinkage be accomplished in the shortest time for synchronized operation with the cutting machine. To stabilize the shapes of flanges stored in the stacker  70  as early as possible, the air blower  80  (see  FIG. 7 ) is incorporated into the flange processing system  100  as a cooling device for blowing cooled air to the flanges in the stacker  70 . 
   As described above, it succeeded in stabilizing the flange shapes by facilitating their shrinkage by using such an air blower. For increased heat efficiency, a stainless steel shield is wrapped around the stacker  70 . This cooling method can facilitate cooling of flanges at low costs, however, for a shorter flange shape stabilization time, another method may be adopted wherein a refrigerator is used that can accommodate the entire stacker. 
   The lathe  50  uses a 6-jaw diaphragm chuck as the chuck  51  that can be attached to the rotational spindle. This is because there is a concern of causing deformation of the flange due to the strain of clamping force when it is clamped to the chuck by means of normal air or oil pressure upon cutting of portions near the chuck. The use of the diaphragm chuck  51  enables flange clamping at a pressure low enough to avoid deformation of the flange. By controlling the pressure applied to the diaphragm chuck  51 , it is possible to achieve delicate cutting condition changes in a case where the shape of a non-processed injection molded article has changed from the previous one. Note that a similar effect can be obtained even when an air balloon chuck is used as the chuck for the lathe  50 . 
   The lathe  50  has a function of removing a thread-like chipping (cutting) by air suction at the spindle  52 . To be more specific, for the purpose of removing chippings during the cutting process, the lathe  50  has a hollow at the spindle through which a suction device (not shown) is connected to the lathe  50  for suctioning chippings by air from inside the spindle  52 . To realize this configuration it is necessary to ensure that cutting depth falls within a proper range (0.05-0.3 mm) during the actual cutting process so that chippings can be readily removed in the form of a thread-like chipping rather than separate chipping pieces. Note that the chipping suction configuration is not particularly limited to the above-noted configuration. 
   An example of a cutting operation will be described specifically below. A gear-equipped flange which is formed by injection molding of resin and has a shape shown in  FIG. 1  is attached to the lathe by clamping it to the 6-jaw chuck at the outer surface of the gear part provided at the end of the flange. 
   Cutting is performed first for the drum engagement part of the flange. Although a proper cutting depth to form a thread-like chipping differs depending on the material, a cutting depth is preferably about 0.15 mm in the case of general polycarbonate. A groove is provided at the drum bumping part of the flange (see  FIG. 2 ). The groove is about 0.1-05 mm in depth and the depth can be appropriately set according to the finish of the drum end. It was confirmed that a groove of 0.2 mm depth can avoid influences of burrs and warpage at the drum end. 
   With the configuration shown in  FIG. 6 , a thread-like chipping is removed by air suction at the spindle of the lathe upon cutting of a shaft hole. For forming a thread-like chipping, the cutting depth is set to about 0.15 mm in the case where the flange is made of polycarbonate. An optimal cutting depth is selected depending on the material. During the cutting of a shaft hole, a thread-like chipping is removed together with other chipping pieces by air suction without any tangle of the thread-like chipping. To avoid generation of burrs at the end of the resultant shaft hole of the flange, which are created as a result of entry of the bite  53  (cutting tool) into the flange shaft core, it is preferable to change the angle at which the bite  53  enters the flange.  FIG. 8  shows a pattern in which the bite  53  moves upon cutting of the shaft hole. With this cutting method, it is possible to avoid generation of burrs during entry of the bite  53 . Furthermore, in order to avoid generation of burrs that are generated by withdrawal of the bite  53 , it is preferable to change the angle in which the bite  53  withdraws out of the flange.  FIG. 9  shows a pattern in which the bite  53  withdraws out of the flange during cutting the shaft hole. With this cutting method, it is possible to avoid generation of burrs during withdrawal of the bite  53 . For example, a cutting process adopting a bite entry angle of 30° and a bite withdrawal angle of 35° gave good results. 
   By cutting the drum engagement part and shaft hole part while clamping the outer surface of the gear part of the flange to the chuck, it succeeded in obtaining low concentricity between the resultant shaft hole and drum engagement part and excellent roundness.  FIG. 11  shows obtained concentricity and roundness values measured by a roundness analyzer made by TOKYO SEIMITSU. 
   A 6-jaw diaphragm chuck was adopted, and it succeeded in achieving precisions shown in  FIG. 11  in mass production of flanges with this chuck. However, the number of jaws may be 6 or more. Pre-evaluations were made with respect to a 3-jaw diaphragm chuck and an 8-jaw diaphragm chuck, and evaluation results are shown in  FIG. 12 . In the case of the 3-jaw diaphragm chuck, there was a tendency that the cross-sectional shape of the processed flange. In order to ensure excellent cutting results, it is preferable that the number of jaws is 6 or more. 
     FIG. 10  shows cutting process data with different pressures (0-0.6 Mpa) applied to the diaphragm chuck. Pressure control can realize delicate cutting condition changes in a case where the shape of a non-processed injection molded article has changed from the previous one. 
   An air balloon chuck may be used as a chuck for clamping a flange to the lathe chuck, in order to clamp the flange with a low pressure as in the case of a diaphragm chuck. The air balloon chuck can provide the same effect as the diaphragm chuck. 
   Flange temperature changes during the actual cutting process causes flange expansion or shrinkage, and hence the cutting amount changes.  FIG. 13  shows variations in outer diameter of flange when room temperature varied from 22° C. to 27° C. As shown in  FIG. 13 , since the outer diameter of flange changes with the temperature, the processing device according to the embodiment is so configured that the variations in dimension among identical flanges can be minimized by controlling the degree of entry of the bite in the flange by feedback control according to the temperature change. For reference temperature data for this feedback control, either work surface temperature or room temperature is selected depending on the circumstances. Note, however, that if the room temperature change can be within about ±2° C. during the course of the cutting process, the effect of this feedback control is little and, since the cutting depth is preferably constant, in actual, room temperature-based control may be selected. 
   Although the descriptions given above are directed to the cutting process for the flange shown in  FIG. 1 , the flange shown in  FIG. 3  can be processed with high precision in much the same way by clamping the outer surface of the gear part of the protruding part of the flange. The flange shown in  FIG. 4  formed by injection molding of resin is attached to the lathe  50  by clamping the protruding part  8 , which is provided to its end, to the 6-jaw chuck  51 . High-precision cutting of the drum engagement part  1  and center hole (shaft hole)  4  is made possible by performing cutting with the protruding part  8  being clamped to the lathe chuck only for once. 
   The present invention can be widely applied to substantially cylindrical mechanical components such as rollers that include plastic flanges attached at either end thereof, whereby roundness and concentricity are improved to increase rotation performance of the components.