JP2014124915A - Extrusion molding machine for rubber roller manufacturing - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a rubber roller extrusion molding machine in which continuous molding of cylindrical rubber molding bodies can be performed stably even in a case a burr is generated at contact parts of ends of core metal parts, upon molding cylindrical rubber molding bodies continuously in the circumference of the plural core metal parts supplied to a crosshead.SOLUTION: For feedback control of supply speed of a core metal to a crosshead based on outer diameter measurement results of cylindrical rubber molding bodies over the core metal fed from a crosshead exit, a control system including first and second outer diameter measuring units, an outer diameter abnormality determining unit, and a control calculating unit is used, the second outer diameter measuring unit for outer diameter abnormality measurement is positioned at a more front side than the first outer diameter measuring unit which outputs measurement results for preparing feedback control directions at the control calculating unit, and when the outer diameter abnormality determining unit determines measurement results of the second outer diameter measuring unit as outer diameter abnormality at the burr part, correction is performed to remove the measurement result showing the burr part from measurement results of the first outer diameter measuring unit, to eliminate influence of the burr part on feedback control.

Description

  The present invention relates to an extrusion molding machine for manufacturing a rubber roller.

  For a charging roller, a developing roller, and the like used in an electrophotographic apparatus, a rubber roller having a cylindrical shape centering on a core metal by covering a cylindrical rubber layer as an elastic layer on an outer peripheral surface of the core metal is used.

   In general, an extrusion molding machine is used in the process of manufacturing a rubber roller. A general extrusion molding machine is a cylindrical rubber in which a rubber material in a molten state and a core metal having a predetermined length are simultaneously fed into a cross head, and the rubber material is uniformly coated to a predetermined thickness. The molded body is configured to be extruded from the outlet of the cross head to the outer periphery of the cored bar. In such an extrusion molding machine, a cylindrical rubber molded body is continuously obtained from the outlet of the crosshead to the outer periphery of the plurality of core bars by continuously supplying a plurality of core bars in series into the extruder. . The thickness of the rubber material layer in the cylindrical rubber molded body can be adjusted by changing the feed speed of the core metal to the cross head and the feed speed of the rubber material to the cross head.

  For example, as shown in FIG. 6A, the rubber roller is formed into a shape in which a central portion of a rubber layer 52 called a crown shape swells around the core metal 51. The cylindrical rubber molded body continuously extruded from the cross head is cut at both ends of each core metal in a separate process in the extruder. Furthermore, a rubber roller is completed through a cooling and solidifying step. If necessary, both end portions of the rubber material layer on the outer periphery of the core metal are shaped to obtain the final shape of the rubber roller. Therefore, as shown in FIG. 6A, both ends of the cored bar 51 are exposed in the completed rubber roller.

  In recent years, with improvement in performance of electrophotographic apparatuses, improvement in shape accuracy of rubber rollers has been demanded. Patent Document 1 discloses a technique for feedback control of an extrusion molding machine for improving the shape accuracy of a rubber roller. In the feedback control of the extrusion molding machine disclosed in Patent Document 1, the feed rate of the core metal and the rubber material are measured based on the measurement result by the measuring instrument that measures the outer diameter of the cylindrical rubber molded body in the vicinity of the outlet of the crosshead. The feed rate is controlled. Thereby, the shape error of the rubber roller is reduced. In the feedback control of the extrusion molding machine disclosed in Patent Document 1, it is possible to reduce an error in the shape of the rubber formed body due to variations in the environment such as physical properties and temperature of the rubber material.

JP 2009-0666808 A

  However, in general, when a rubber roller is manufactured by continuously supplying a plurality of cores to the cross head, as shown in FIG. 6B, it corresponds to a portion where the end faces 51a of the cores 51 are in contact with each other. A burr 53 in which the rubber material rises sharply tends to occur in the portion. The portion of the rubber material where such burrs 53 are formed has a large outer diameter. Therefore, in the extrusion molding machine disclosed in Patent Document 1, feedback control is applied in accordance with the outer diameter of the burr 53, causing a large fluctuation in the feed rate of the core metal and saturation of the operation amount, and normal extrusion molding operation is performed. It was sometimes disturbed. In such a case, it may take time to return to a normal extrusion operation.

  Accordingly, an object of the present invention is to provide a rubber roller extrusion molding machine capable of stably molding a rubber roller even if burrs are generated in the rubber material layer around the core metal.

An extrusion molding machine for producing a rubber roller according to the present invention,
A crosshead for forming a cylindrical rubber molding on the outer periphery of the core metal;
An extruder having a cylinder for feeding a molten rubber material to the crosshead;
A transport roller for continuously transporting a plurality of core bars to the cross head in the axial direction of the core bar; and a drive means for the transport rollers;
In an extrusion molding machine for producing a rubber roller having
A first outer diameter measuring instrument for measuring the outer circumference of the cylindrical rubber molded body extruded from the outlet of the crosshead;
A second outer diameter measuring instrument that is provided between the outlet of the crosshead and the first outer diameter measuring instrument and measures the outer diameter of the cylindrical rubber molded body;
An outer diameter abnormality determination device,
Calculating a feedback control command for controlling the speed at which the core metal is fed into the cross head, and outputting the feedback control command to the driving means of the transport roller;
With
The outer diameter abnormality determination device, as an outer diameter measurement result to be sent to the control arithmetic unit for calculating the feedback control command,
(1) If it is determined from the second outer diameter measurement result that there is no outer diameter abnormality, the measurement result of the first outer diameter measuring device is output,
(2) If it is determined from the second outer diameter measurement result that there is an outer diameter abnormality, the measurement is performed by correcting the outer diameter measurement result from the first outer diameter measuring instrument to exclude the measurement result related to the outer diameter abnormality. An extrusion molding machine for producing a rubber roller.

  ADVANTAGE OF THE INVENTION According to this invention, even if a burr | flash generate | occur | produces in the rubber material around a metal core, the extrusion molding machine for rubber roller manufacture which can shape | mold rubber cola stably can be provided.

It is a schematic block diagram of the extrusion molding machine of the rubber roller which concerns on one Embodiment of this invention. It is a conceptual diagram of the measurement result of a 1st outer diameter measuring device and a 2nd outer diameter measuring device. It is an output flow figure of an outer diameter abnormality judgment device. It is a conceptual diagram of the output waveform from an outer diameter abnormality determination device. It is a conceptual diagram of the output waveform from an outer diameter abnormality determination device. It is a conceptual diagram of a rubber forming body.

  An extrusion molding machine for producing a rubber roller according to the present invention includes an extruder, a cored bar conveying roller, a cross head for forming a cylindrical rubber molded body on the outer periphery of the cored bar, a driving unit for the conveying roller, A first outer diameter measuring device and a second outer diameter measuring device for measuring the outer periphery of the cylindrical rubber molded body, an outer diameter abnormality determining device, and a control computing device are included.

  The extruder has a cylinder for extruding a molten rubber material by rotation of a screw and feeding it into a crosshead, and the crosshead is connected to the tip of the cylinder. At the center of the cross head, a tubular member having a through-hole through which the cored bar passes is disposed, and the rubber material extruded from the extruder is introduced into a region around the tubular member. Furthermore, the outlet of the cross head is provided with a discharge port for a molten rubber material surrounding the periphery of the through hole through which the cored bar passes. The molten rubber material is discharged from the discharge port, and the outer periphery of the core metal pushed out from the outlet of the through hole is covered with the molten rubber material, whereby a cylindrical molded body can be obtained.

  As the rubber material to be fed into the extruder, a material having a composition according to the intended use of the rubber roller as a charging roller, a developing roller or the like and having physical properties capable of feedback control is appropriately selected.

  The feed speed of the cored bar in the crosshead can be controlled by adjusting the rotation speed of the conveying roller. The cylinder covered on the outer periphery of the cored bar by the heating temperature of the molten rubber material, the feed rate of the cored bar, etc. The outer diameter of the rubber molded product can be controlled.

  The cylindrical rubber molded body formed in common with the plurality of cores extruded from the cross head is cut at the end of each core and separated for each core. A cored bar having a cylindrical rubber molded body that is individually separated becomes a rubber roller through a cooling and shaping process.

  In the vicinity of the outlet of the crosshead of the extrusion molding machine according to the present invention, a second outer diameter measuring instrument and a first outer diameter measuring instrument are arranged in order from the outlet of the crosshead in the extrusion direction of the cylindrical rubber molded body. Yes. These outer diameter measuring instruments measure the outer periphery of a cylindrical rubber molded body extruded from the outlet of the crosshead, and can be constituted by a laser outer diameter measuring instrument or the like. These outer diameter measuring devices together with an outer diameter abnormality determining device and a control computing device form a feedback control system for the core metal conveying roller.

  An outer diameter measurement result obtained by the first outer diameter measuring instrument is used for feedback control of the feed rate of the cored bar by the transport roller. Specifically, the outer diameter measurement result from the first outer diameter measuring instrument is input to the control arithmetic unit, and a feedback control command for controlling the speed at which the mandrel is fed into the crosshead is calculated. Fade back control of the feed rate of the cored bar is performed by outputting to the driving means of the transport roller.

  In the present invention, before the measurement with the first outer diameter measuring device, the outer diameter is measured with the second outer diameter measuring device, and the outer diameter is measured using the measurement result with the second outer diameter measuring device. The presence / absence of an outer diameter abnormality in the abnormality determining device is determined. To determine whether or not an outer diameter abnormality has occurred, compare the information on the predetermined outer diameter of the cylindrical rubber molded body that has been input to the outer diameter abnormality determining device with the measurement results obtained from the outer diameter measuring device. Done in For example, a threshold value is set for a difference between a predetermined outer diameter at a predetermined position of the cored bar set in advance and an actual measurement value, and when the difference exceeds the threshold value, it is determined that the outer diameter is abnormal. For example, it is possible to determine the occurrence of a burr portion as an outer diameter abnormality by comparing the measured value with data relating to a preset outer diameter abnormality such as a burr portion.

In the present invention, the following selection is performed on the outer diameter measurement result used for the feedback control of the core metal supply speed in accordance with the determination of the presence or absence of the outer diameter abnormality by the outer diameter abnormality determiner. In other words, the outer diameter abnormality determination device, as an outer diameter measurement result sent to the control arithmetic unit for calculating the feedback control command,
(1) If it is determined from the second outer diameter measurement result that there is no abnormality in the outer diameter, the measurement result of the first outer diameter measuring device is output,
(2) If it is determined from the second outer diameter measurement result that there is an outer diameter abnormality, correction is performed by excluding the measurement result related to the outer diameter abnormality from the outer diameter measurement result from the first outer diameter measuring device.

  For a plurality of cores sequentially supplied in series in the cross head, the rubber material swelled at the abutting portion between the rear end of the core core fed in first and the front end of the core metal following this A burr part may occur. Even if the outer diameter of the coating layer used as a rubber roller is formed with high accuracy, if such burr formation is recognized as an abnormal outer diameter, feedback control is applied and large fluctuations or manipulations in the feed rate of the mandrel There was a case where the amount of saturation was generated and the normal extrusion operation was hindered. In such a case, it may take time to return to a normal extrusion operation. Therefore, in the present invention, processing of the outer diameter measurement result according to the presence or absence of the outer diameter abnormality according to (1) and (2) described above is performed. By this processing, even when an outer diameter abnormality corresponding to the burr portion occurs, the feedback using the outer diameter measurement result obtained from the first outer diameter measuring instrument without stopping the continuous molding of the cylindrical rubber molded body. Control can be performed.

The combination of the first outer diameter measuring instrument and the second outer diameter measuring instrument preferably satisfies at least one of the following conditions (A) to (C).
(A) The measurement resolution (measurement accuracy) of the first outer diameter measuring instrument is higher than that of the second outer diameter measuring instrument.
(B) The measurement response speed (response response) of the second outer diameter measuring instrument is faster than that of the first outer diameter measuring instrument.
(C) The installation width in the extrusion direction of the metal core from the crosshead outlet of the second outer diameter measuring instrument is narrower than that of the first outer diameter measuring instrument.

  Regarding the condition (A), since the outer diameter measurement result from the first outer diameter measuring instrument is used for feedback control, the first outer diameter measuring instrument having a measurement accuracy necessary for feedback control is used. On the other hand, the second outer diameter measuring device only needs to be able to detect an outer diameter abnormality having a large outer diameter change, and does not need to have measurement accuracy for use in feedback control. That is, the requirements regarding the measurement accuracy in the second outer diameter measuring instrument are relaxed as compared with the first outer diameter measuring instrument.

  With respect to the condition (B), the second outer diameter measuring instrument is used for determining an outer diameter abnormality, and the measurement result is used for correcting the measurement result from the first outer diameter measuring instrument. Therefore, before the measurement result of the first outer diameter measuring device at the same position of the cylindrical rubber molded body that is the outer diameter measuring object is output to the outer diameter abnormality determining device, the second outer diameter measuring device The measurement result needs to be output to the outer diameter abnormality determiner with a time difference that can secure a sufficient time for determining the outer diameter abnormality. The output time difference between the measurement results from the first outer diameter measuring instrument and the second outer diameter measuring instrument at the same position of the cylindrical rubber molding is the distance between these measurement points when these response responses are the same. And the speed of the mandrel moving between these measurement points. The larger the distance between the measurement point at the first outer diameter measuring instrument and the measurement point at the second outer diameter measuring instrument, the greater the difference in output time between measurement results. On the other hand, it is preferable to install the first outer diameter measuring instrument closer to the crosshead outlet in order to perform feedback control more efficiently. Therefore, by using a second outer diameter measuring device having a response response earlier than that of the first outer diameter measuring device, the distance between the measurement points of the first outer diameter measuring device and the second outer diameter measuring device can be determined. By shortening, the measurement point of the second outer diameter measuring instrument can be brought closer to the crosshead outlet. Further, when the condition (A) and the condition (B) are combined, it is preferable to use an outer diameter measuring instrument having a relatively low detection accuracy and a quick response response as the second outer diameter measuring instrument.

  For condition (C), the first outer diameter can be reduced by reducing the installation width of the second outer diameter measuring instrument (the width in the feed direction of the core bar occupied by the outer diameter measuring instrument in the extrusion molding machine). The measurement point on the measuring instrument can be brought closer to the crosshead outlet.

Example 1
FIG. 1 is a schematic configuration diagram shown as a vertical cross-sectional view of a rubber roller extrusion molding machine 100 according to an embodiment of the present invention. The extrusion molding machine 100 is an apparatus for manufacturing a cylindrical rubber molded body 7 in which the core metal 1 is placed in the center by uniformly covering the entire circumference of the core metal 1 with a rubber material.

  The extrusion molding machine 100 includes a crosshead 3 into which the core metal 1 and a molten rubber material are fed, a plurality of rollers 6 that feed the core metal 1 into the crosshead 3, and a cylinder 4 that feeds the rubber material 2 into the crosshead 3. And are provided. The roller 6 feeds a plurality of core bars 1 in series to the crosshead 3 in series in the axial direction. The cylinder 4 includes a screw 5 inside, and feeds the molten rubber material into the crosshead 3 by the rotation of the screw 5. When the core metal 1 is fed into the crosshead 3, the entire circumference is covered with the molten rubber material 2 fed from the cylinder 4 into the crosshead. Then, the core metal 1 is fed out from the outlet of the cross head 3 as a cylindrical rubber molded body 7 with the rubber material 2 attached to the surface. In the extrusion molding machine 100, a so-called crown-shaped cylindrical rubber molded body 7 in which the outer diameter of the coating layer made of the rubber material 2 is large is formed at the center portion in the longitudinal direction of each cored bar 1. For this purpose, the feed speed of the core 1 by the roller 6 and the feed speed of the rubber material 2 from the cylinder 4 are changed.

  The thickness of the rubber material 2 adhering to the core metal 1 becomes thinner when the feed speed of the core metal 1 to the crosshead 3 by the roller 6 is increased, and becomes thicker when the feed speed is decreased. Further, the thickness of the coating layer made of the rubber material 2 attached to the core metal 1 increases as the feed speed of the rubber material 2 from the cylinder 4 to the crosshead 3 increases, and decreases as the feed speed decreases.

  As described above, the thickness of the rubber material 2 attached to the core metal 1 can be controlled by the feeding speed of the core metal 1 to the cross head 3 and the feeding speed of the rubber material 2 to the cross head 3. . However, the speed of response of the change in the thickness of the rubber material 2 around the core metal is faster than the feed speed of the rubber material 2 to the cross head 3 than the feed speed of the core metal 1 to the cross head 3. . Therefore, it is more effective to adjust the thickness of the coating layer made of the rubber material 2 attached to the core metal 1 by controlling the feed speed of the core metal 1 to the cross head 3 by the roller 6. The feed speed of the core 1 to the crosshead 3 by the roller 6 is adjusted by the rotational speed of the motor 8 connected to the roller 6. The motor 8 includes an encoder 9, and the encoder 9 can detect the rotation speed and the number of rotations of the motor 8.

  On the other hand, the feed speed of the rubber material 2 from the cylinder 4 can be controlled by the rotational speed of the screw 5. The screw 5 includes an induction motor (not shown), and the rotational speed of the screw 5 can be detected by the induction motor. The cylindrical rubber molded body 7 sent out from the outlet of the crosshead 3 is received by the take-up machine 15 one by one per cored bar, and is sequentially placed on a pallet (not shown).

  Next, feedback control in the extrusion molding machine 100 will be described. The feedback control system includes a first outer diameter measuring device 10, a second outer diameter measuring device 11, an outer diameter abnormality determining device 12, a control calculator 13, and a driver 14. The first outer diameter measuring instrument 10 is disposed in the vicinity of the outlet of the crosshead 3, that is, in front of the moving direction of the core metal, and measures the outer diameter of the cylindrical rubber molded body 7 fed out from the outlet, and the measurement is performed. The result is transmitted to the outer diameter abnormality determination device.

  The second outer diameter measuring device 11 is disposed between the crosshead 3 and the outer diameter measuring device 10, and measures the outer diameter of the cylindrical rubber molded body 7 in the same manner as the first outer diameter measuring device 10. It is transmitted to the outside diameter abnormality determination device.

  The time for the position to reach the first outer diameter measuring device after the rubber adheres to a certain position of the core metal 1 is a dead time for the feedback control system. In order to improve the performance of the feedback control system, it is desirable that the dead time is small, and the first outer diameter measuring instrument 10 is preferably provided as close to the crosshead 3 as possible. However, since the first outer diameter measuring instrument 10 uses the measurement result as a feedback signal, high measurement accuracy is required, and there are restrictions on arrangement due to physical factors of the size. On the other hand, since the second outer diameter measuring device 11 is used for determining an outer diameter abnormality, the first outer diameter measuring device 10 is not required to be as accurate as the first outer diameter measuring device 10, and a small one can be used. It can be provided closer to the crosshead 3 than the vessel 10.

  The function of the outer diameter abnormality determination device 12 will be described with reference to FIGS.

  FIG. 2 is a conceptual diagram of measurement results of the first outer diameter measuring instrument 10 and the second outer diameter measuring instrument, and is exaggerated for explanation based on the actually measured waveform. In addition, the vertical axis | shaft in FIG. 2 represents the layer thickness of the cylindrical rubber molding.

The measurement result of the second outer diameter measuring instrument 11 shown in the upper part of FIG. 2 can be obtained earlier by Δt than the measurement result of the first outer diameter measuring instrument 10 shown in the lower part of FIG. This Δt is substantially the same as that obtained by dividing the distance between the measurement points of the first outer diameter measuring instrument 10 and the second outer diameter measuring instrument 11 in the core feed direction by the core feed speed.

  FIG. 3 shows a flowchart of the output method of the feedback control output sent to the control arithmetic unit 13 in the outer diameter abnormality determining unit 12. Using the measurement result of the second outer diameter measuring instrument 11 that can be obtained earlier than the first outer diameter measuring instrument 10, it is determined whether or not the measurement result is a burr portion, that is, whether or not the outer diameter is abnormal. The burr portion of the measurement result has a unique shape having a steep change as shown in FIG. 2, and the burr portion can be determined based on this waveform. When the measurement result is a burr portion and it is determined that the outer diameter is abnormal, a correction signal is output. When it is determined that it is not a burr part, the measurement result of the measured value by the first outer diameter measuring device is output.

  The determination of the outer diameter abnormality in the outer diameter abnormality determination unit 12 and the output of the data for calculating the feedback control command to the control calculator 13 are performed as follows. First, the data regarding the change with time of the outer diameter measurement value from the second outer diameter measuring device 11 is taken into the outer diameter abnormality determining device 12 (step S301). Next, the data from the second outer diameter measuring device is compared with data relating to an outer diameter abnormality corresponding to a preset burr portion to determine whether there is an outer diameter abnormality (step S302). If it is determined in step S302 that there is no abnormality in the outer diameter, “NO”, the first outer diameter measuring instrument 10 on the portion of the cylindrical rubber molded body having no outer diameter abnormality that has passed the measurement point of the second outer diameter measuring instrument. Is output to the control calculator 13 (step S303). If it is determined that the outer diameter abnormality is “YES” in step S302, a correction signal obtained by deleting the data indicating the outer diameter abnormality from the measurement result from the first outer diameter measuring device 10 is output to the control calculator 13 (step S304). ).

  FIG. 4 shows an example of a waveform output to the control calculator 13 when the outer diameter abnormality determining unit 12 determines that there is no outer diameter abnormality.

  FIG. 5 shows the waveform of the feedback control output, which is the correction signal output of the outer diameter abnormality determiner 12. When the “outer diameter abnormality determination” in the outer diameter abnormality determination device is “YES”, the waveform corresponding to the burr portion is removed from the waveform as the measurement result from the first outer diameter measurement device 10 in FIG. A correction signal as shown is output from the outer diameter abnormality determining device instead of the waveform from the first outer diameter measuring device. In forming the correction signal, the measurement result of the first outer diameter measuring device 10 for the portion determined to be “with burr” based on the measurement result from the second outer diameter measuring device may be used as basic data. . Although it is possible to determine an abnormality in the outer diameter using the measurement result of the first outer diameter measuring instrument 10, the measurement result of the first outer diameter measuring instrument 10 is directly sent to the control calculator 13 during the determination processing time. Since the feedback control is performed, the influence of the burr portion remains. When the present invention is used, the measurement result of the second outer shape measuring instrument that can be obtained earlier in time is used for the determination of the outer diameter abnormality, so that the influence of the burr portion can be removed without delay.

  The control calculator 13 controls the rotational speed or the rotational speed of the motor 8 via the driver 12 so that the outer diameter error, which is the difference between the target outer diameter of the cylindrical rubber molded body 7 and the feedback control output, is reduced. . Thereby, the metal core 1 is fed into the cross head 3 by the roller 6 so that the measured outer diameter of the cylindrical rubber molded body 7 approaches the target outer diameter. With the above operation, the cylindrical rubber molded body 7 can be stably molded without being affected by the burr portion.

DESCRIPTION OF SYMBOLS 1 Metal core 2 Rubber material 3 Crosshead 4 Cylinder 5 Screw 6 Roller 7 Rubber forming body 8 Motor 9 Encoder 10 First outer diameter measuring device 11 Second outer diameter measuring device 12 Outer diameter abnormality determining device 13 Control calculator 100 Extrusion molding Machine

Claims (5)

A crosshead for forming a cylindrical rubber molding on the outer periphery of the core metal;
An extruder having a cylinder for feeding a molten rubber material to the crosshead;
A transport roller for continuously transporting a plurality of core bars to the cross head in the axial direction of the core bar; and a drive means for the transport rollers;
In an extrusion molding machine for producing a rubber roller having
A first outer diameter measuring instrument for measuring the outer circumference of the cylindrical rubber molded body extruded from the outlet of the crosshead;
A second outer diameter measuring instrument that is provided between the outlet of the crosshead and the first outer diameter measuring instrument and measures the outer diameter of the cylindrical rubber molded body;
An outer diameter abnormality determination device,
Calculating a feedback control command for controlling the speed at which the core metal is fed into the cross head, and outputting the feedback control command to the driving means of the transport roller;
With
The outer diameter abnormality determination device, as an outer diameter measurement result to be sent to the control arithmetic unit for calculating the feedback control command,
(1) If it is determined from the second outer diameter measurement result that there is no outer diameter abnormality, the measurement result of the first outer diameter measuring device is output,
(2) If it is determined from the second outer diameter measurement result that there is an outer diameter abnormality, the measurement is performed by correcting the outer diameter measurement result from the first outer diameter measuring instrument to exclude the measurement result related to the outer diameter abnormality. An extrusion molding machine for manufacturing a rubber roller.   The extrusion molding machine for manufacturing a rubber roller according to claim 1, wherein the abnormality in the outer diameter is caused by a burr portion generated at a contact portion of the end portions of the plurality of continuously supplied core bars.   The rubber roller extrusion molding according to claim 1 or 2, wherein an installation width of the second outer diameter measuring device in the axial direction of the core metal is smaller than an installation width of the first outer diameter measuring device in the axial direction of the core metal. Machine.   The rubber roller extrusion molding machine according to any one of claims 1 to 3, wherein a measurement resolution of the second outer diameter measuring instrument is coarser than a measurement resolution of the first outer diameter measuring instrument.   The rubber roller extrusion molding machine according to any one of claims 1 to 4, wherein a response speed of the second outer diameter measuring instrument is lower than a response speed of the first outer diameter measuring instrument.

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