JP3236787B2 - Method for manufacturing reinforced insulator and apparatus for manufacturing reinforced insulator - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a block-shaped pre-molded insulator to be disposed at a power cable connecting portion or the like, and more particularly to a method of manufacturing a block-shaped insulator and an apparatus used for the manufacturing.

[0002]

2. Description of the Related Art When connecting a large-capacity power cable having a large conductor cross-sectional area, such as a CV cable used for a high-voltage transmission line, the conductor is connected in a tunnel or in a manhole. The connection is provided with a coating using a plastic material. As the coating of the connection portion, for example, as shown in Japanese Patent Application Laid-Open No. 5-174936, a mold is arranged so as to cover the conductor connection portion, and a plastic material is extruded into the mold to form a reinforcing insulator. We are molding. However, installing the reinforcing insulator at a cable connection site has a problem that the installation efficiency is not good because a clean room is arranged at the installation site, and work at a very narrow site is forced. . Therefore, in order to solve the above-mentioned problem, the reinforcing insulator is prepared in advance at a factory, and at a cable connection site, only a cable to be connected to the reinforcing insulator is inserted. It has been proposed that this can be easily performed.

It is known to use a method as disclosed in, for example, Japanese Patent Application Laid-Open No. 8-336835 in order to use a reinforcing insulator manufactured in a factory. In the conventional cable connecting means, a copper conductor connector is fixed to a distal end of a cable conductor, and the conductor connector attached to the distal end of the two cable conductors to be connected is formed of a copper cylindrical connector. The cable is inserted so as to be opposed to the conductor joint so that the cable is conducted. Further, in the conventional example, each of the two conductor connectors to be inserted into the cylindrical conductor joint is provided with locking means between the two conductor connectors and the cylindrical conductor joint. In the state where the conductor connector is inserted, the step formed on the inside of the conductor joint and the step formed on the tip of the conductor connector are locked, so that the conductor connector has a cylindrical conductor joint. It does not come off.

[0004] A connection portion for a power cable as shown in the conventional example is configured, for example, as shown in FIG. 12, and a connection portion 8 for a cable includes two cables 1.
Are provided integrally with the conductors 2 and 2a, respectively, at the tips of the conductors 2 and 2a. And the conductor connector 6 ...
Is inserted into the cylindrical conductor joint 7 to constitute a means for setting the conductive state between the conductors via the conductor joint. In the cable connection portion 8, a high-voltage shield electrode 9 is disposed at a position corresponding to the cylindrical conductor joint 7, and a reinforcing insulator 10 integrally formed in a cone shape with a predetermined length is disposed around the high-voltage shield electrode 9. I do. The reinforcing insulator 10 is formed as a single piece using a rubber / plastic material such as an uncrosslinked polyethylene resin to which a crosslinking agent has been added,
After the reinforcing insulator is positioned at the cable connection portion, the plastic material is molded and cross-linked by applying a heating and pressurizing action to form an insulator.

In the cable connection section, a reinforcing insulator 1
A shielding layer 13 is provided around 0, a waterproof mixture 14 is formed at a predetermined thickness on the outer periphery thereof, and a metal protection tube 15 is arranged on the outer periphery of the waterproof mixture 14. Further, when forming an insulated connecting portion with respect to the protective tube 15, the insulating tube 16 is arranged at a predetermined position, and a terminal seat 17 is arranged with respect to the protective tube 15 to be connected to a cross bond or the like. Means are provided. Furthermore, the waterproof layer 18 is disposed so as to cover the connection portion between the both ends of the insulating tube 16 and the cable sheath tube, and by forming the waterproof layer 18 by means such as winding an insulating tape, Protection tube 15
This constitutes means for preventing moisture or the like from entering the inside of the device.

[0006]

The reinforcing insulator is formed by using a rubber / plastic material.
Since the size of the cable to be connected is different depending on the conductor cross-sectional area or the like, the cable is first formed into a cylindrical shape, and then cut into a predetermined shape. However, even when a plastic material is cast into a mold to form a cylindrical body, the diameter changes when the plastic is cooled after casting, and the problem of removing the core is troublesome. There is. Further, when forming the reinforcing insulator, it is necessary to perform a forming process using a lathe or the like so that foreign substances do not adhere in a clean room, and cutting is performed using a general lathe or the like. Even in this case, it is necessary to prevent oil or the like from adhering to the surface of the reinforcing insulator. Further, the reinforcing insulator is required to be configured as having a different shape in accordance with the cable conductor size and the like, but when using a general-purpose lathe or the like for such a property of the reinforcing insulator. However, there is a problem that the production efficiency cannot be improved.

SUMMARY OF THE INVENTION The present invention addresses the above-mentioned problem of forming a reinforcing insulator, and has as its object to provide a method of manufacturing a reinforcing insulator and a processing apparatus suitable for processing of a reinforcing insulator. I have.

[0008]

A method for manufacturing a reinforced insulator according to the present invention comprises the steps of positioning a core and a high-voltage shield electrode in a mold, injecting a plastic material, and forming a cylindrical block. Removing the cylindrical block from the mold, extracting the core, mounting the molding support in accordance with the molding process, and supporting both ends of the molding support shaft with the rotating support member of the processing device. And a step of cutting the cylindrical block with a cutting tool provided in the processing apparatus. Further, in the present invention, in addition to the method, when extracting a core from the cylindrical block body, a turntable provided with a mechanism for fixing and holding the cylindrical block body and a mechanism for performing vertical movement and horizontal rotation. Then, after positioning the cylindrical block, after extracting one core, the vertical position and horizontal rotation of the turntable are performed to change the position of the cylindrical block, and then the other core is extracted. When the core is extracted, a low-speed rotation can be given to the core. Further, in the present invention, the molding support disposed in the cylindrical block in accordance with the cutting process of the cylindrical block is a shaft inserted into a through hole of the cylindrical block, and a shaft inserted from both sides of the cylindrical block. It is possible to use an end fixing member having a side flange to be pressed, and an end flange provided at both ends of the shaft and attached to a supporting member provided on a rotation supporting member of the processing apparatus.

A processing apparatus for manufacturing a reinforced insulator according to the present invention includes a turntable provided with a mechanism for fixing and holding a cylindrical block body, and a mechanism for performing vertical movement and horizontal rotation.
A support member for holding both ends of a shaft of a molding support attached to a cylindrical block, a driving unit for applying rotation to the one support member, and an end for rotatably supporting the other support member A support member, a slide frame that supports the support member provided with the driving unit, and a mechanism that moves the slide frame in the axial direction of the cylindrical block body;
The tool comprises a high-speed rotation means and a low-speed rotation means for the support member arranged on the slide frame, and a bite device provided with guide means for holding the bite and corresponding to cutting.

[0010] By using the above-described method for manufacturing a reinforcing insulator, a cylindrical cylindrical block is first cast and formed, and the cylindrical block is cut to form an arbitrary outer shape. This makes it possible to manufacture a reinforcing insulator having a required shape for a cable connection portion. When extracting the core from the cylindrical block, the cylindrical block is fixed and held on a turntable, and the core is locked to a drive / support member provided in the processing device and then extracted.
Since the other core is engaged with the drive / support member to perform the extraction operation, the operator can easily perform the extraction operation without having to rotate the cylindrical block horizontally. Become. Furthermore, the support for molding used to support the cylindrical block body during the cutting process holds and fixes both ends of the cylindrical block body using the end fixing members with respect to the shaft, so that the rotation of the shaft causes the eccentricity of the cylindrical block body. It does not cause rotation, and it is possible to easily cope with the cutting of the cylindrical block by the cutting tool.

The processing apparatus used for manufacturing the reinforced insulator according to the present invention comprises a turntable used for extracting a core from a cylindrical block and for positioning a mounting support for mounting in accordance with cutting. Because of the provision, it is possible to prepare for cutting without touching the cylindrical block body. In addition, the processing device is configured to move the cylindrical block in the axial direction and to rotate the shaft at a low speed and a high speed with respect to a driving / supporting member that supports one of the core and the shaft mounted on the cylindrical block. The mechanism that gives low speed rotation when removing the core from the cylindrical block body and the operation that performs high speed rotation when cutting with a cutting tool can be performed accurately. Becomes

[0012]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The order of processing the reinforcing insulator of the present invention will be described with reference to the illustrated example. The example shown in FIG. 1 shows a case where a cylindrical block body of a reinforcing insulator is cast and molded, and two cores 27 are placed in a mold 25.
The molten plastic material is injected from an injection port 26 provided in a mold 25. The two cores 27, 27a are configured such that the abutting end portions 29, 29a have a diameter corresponding to the inner diameter of the high voltage shield electrode 9, and form tapered portions 28, 28a corresponding to both side portions of the high voltage shield electrode. are doing. Then, a plastic material is injected into the mold 25 and cooled, so that the cylindrical block 20 shown in FIG.
However, as the plastic material, uncrosslinked polyethylene or the like is used.

The cylindrical block 20 taken out of the mold has cores 27, 27 on both sides of the cylinder.
Since a is attached in a skewered manner, it is necessary to first remove the core. Therefore, in this embodiment, as shown in FIG. 2, the cylindrical block body 20 is fixed and held by the clamp members 65 and 65 a provided on the turntable 60, and the core 27 is driven by using the drive / support member 50. After removing and then turning the turntable 60 horizontally by 180 °, the core 27a is positioned corresponding to the driving / supporting member 50, and the core 27a is extracted by the driving / supporting member.

The drive used for removing the core
The support member 50 is configured by disposing the slide frame 44 with respect to the frame of the processing apparatus.
4 is moved to the left side of the figure, so that the core is extracted from the cylindrical block body 20. Further, when the core does not easily come out of the cylindrical block, the action of rotating the core by the drive transmission device 54 is provided, and the core is released from the attached state to the cylindrical block, and then the core is removed. Let it do. Therefore, the clamping member 6
5, 65a is used to fix the cylindrical block body 20 to the turntable so that the core can be easily extracted.

As described above, when the core is extracted from the cylindrical block, the core is formed integrally with the high-voltage shield electrode embedded in the cylindrical block. In the state described above, it is not possible to cope with the next cutting step of the cylindrical block body. Therefore, in the next stage, as shown in FIGS. 3 and 4, the molding support 30 is mounted on the cylindrical block body 20 so as to cope with the cutting of the cylindrical block body. As the molding support 30, a shaft 31 is inserted into a through hole at the center of the cylindrical block body, and end fixing members 35 and 35a are arranged at both side ends of the cylindrical block body. The cylindrical block is fixedly held to the shaft 31.

The end fixing members 35 and 35a have insertion portions 36 inserted into the ends of the through holes provided in the cylindrical block body.
And a large-diameter side flange 37 that presses against the side surface of the cylindrical block body. By rotating and rotating through the shaft 31, the cylindrical block body is held so as not to be eccentrically rotated. Further, end flanges 32 and 32a are integrally provided at both ends of the shaft 31 in correspondence with holding members of the processing device, and the end flanges correspond to holding portions of the processing device. Bolt hole 3
Are provided at predetermined intervals. As described above, the cylindrical block body 20 is supported by the forming support 30 and supplied to the cutting step shown in FIG. 5, and the cutting and removing unit 21 of the cylindrical block body 20 is bitten using a cutting device described later. Then, a work of shaving and removing is performed to obtain a shape as shown in FIG. Then, the reinforcing insulator 10 after the molding operation is completed, as shown in FIG.
It has a cone shape with a through hole 11 for inserting a cable at the center in the thickness direction, and has a shape that can be arranged at the center of the cable connection portion.

[0017]

Next, a description will be given of the configuration of a processing apparatus used for processing a cylindrical block body as described above and manufacturing a reinforcing insulator. The examples shown in FIGS. 7 to 11 show the configuration of a processing apparatus used for cutting a cylindrical block body to form a reinforcing insulator having a predetermined shape. The entire configuration of the processing device 40 is shown in FIGS. 7 and 8 and is configured as a device substantially similar to a general lathe device. In this example, the cylindrical block body 2 is used.
The case where the operation of extracting the core from 0 is performed is shown. Further, in the processing device 40, a turntable 60 for supporting the cylindrical block body 20 taken out of the mold is arranged, and the core device is taken out as shown in FIG. A mechanism for cutting the cylindrical block body 20 using the cutting tool provided at 70 and molding the cylindrical block body 20 as a reinforcing insulator. In the processing apparatus, when the core is extracted from the cylindrical block, the driving / supporting member 50 is used. Further, as shown in FIGS. 3 and 4, at the time of cutting the cylindrical block body 20, the drive / support member 50 and the end support member 55 are used to support both ends of the shaft penetrating the center. The end flange of the shaft is attached to the supporting members 51 and 56 provided on the driving / supporting member and the end supporting member via fixing bolts or the like.

Since the end supporting member 55 functions to support the shaft during the processing of the cylindrical block, the end supporting member 55 is supported at the distal end with respect to the bearing member fixed on the frame 41. The shaft provided with the member 56 is rotatably supported. The drive / support member 50 is disposed on the slide frame 44, and when the core is pulled out, the support member 51 is locked to the core so that the slide frame 4
4 is moved on the slide bed 42 in the left direction in the figure to perform an operation of extracting the core from the cylindrical block body. A pull-out device 45 is arranged to move the slide frame 44. In the pull-out device 45, a driven bracket 48 of the slide frame 44 is arranged with respect to a drive shaft 46 driven by a driving device 47. A mechanism for moving the slide frame according to the rotation of the shaft 46 is configured.

Further, a drive motor 53 for rotating the support member at a low speed when the core is pulled out is provided on the support member 51 supported by the slide frame 44. A drive motor 52 for rotating the block body is provided, and a mechanism for transmitting the rotation of the drive motor to the support member 51 via the drive transmission device 54 is provided. In addition to the driving mechanism corresponding to the driving / supporting member 50, in the processing device 40, when the core is extracted from the cylindrical block, a turntable 60 for fixing and holding the cylindrical block is provided. Tool used for cutting the tool, and a tool device 70 as a support and guide mechanism for the tool
Are provided. Further, the turntable 60 is provided with a mechanism for moving in the vertical movement direction by a lifting / lowering / rotating device 61 and a mechanism for rotating the turntable 60 in the horizontal direction about the vertical axis. Clamp members 65 and 65a for holding are provided so as to cope with the work of extracting the core from the cylindrical block body.

The turntable 60 and its driving mechanism,
The detailed structure of the mechanism for holding the cylindrical block body is shown in FIGS.
As shown in FIG. 9, the upper clamp members 65 and 65 a fixedly arrange the lower clamp member 66 on the turntable, and attach the upper clamp member 67 to the lower clamp member 66 via the hinge 68. It is provided to be swingable. Then, the cylindrical block body 20 is fixedly held between the upper and lower clamp members 66 and 67 to cope with the work of extracting the core from the cylindrical block body. Further, a drive mechanism 61 for transmitting the rotation of a drive motor 62 is disposed below the turntable 60, and the turntable 60 is configured to rotate in a horizontal direction about a drive shaft 63. Furthermore, the pin 6 is placed on the frame of the processing device.
4, 64a are provided so as to protrude, and the pins are inserted into holes provided in the turntable 60 so that accurate positioning can be performed.

In the turntable, as described in FIG. 2, two clamp members 65 and 65a are provided.
By fixing and holding the cylindrical block body by means of, the end of one of the cores is fixed to the support member 51, and the slide frame 44 holding the drive / support member 50 is moved via the pull-out device 45, whereby the core is From the cylindrical block body. In the case where the core does not come out of the cylindrical block at the time of removing the core, an action of rotating the support member at a low speed by using the drive motor 53 is given, and the core in close contact with the plastic material is removed. The slide frame 44 is moved to the left in the drawing while giving a peeling action. Then, after extracting one of the cores 27 from the cylindrical block body, the turntable is horizontally moved by 18 degrees.
After rotating by 0 °, the other core 27 a is fixed to the support member 51, and the two cores are taken out by rotating the support member 51 and moving the slide frame 44.

During the horizontal rotation of the turntable 60, there is a risk that the end of the cylindrical block or the turntable may abut on the cutting tool 70 or other protruding members placed at the right end in the drawing. Therefore, in the present embodiment, a vertical movement mechanism using a lifting / lowering / rotating device 61 is provided in order to vertically move the cylindrical block body with respect to the turntable 60 to a height at which the cylindrical block body can be safely rotated. Then, as shown in FIG. 10, the turntable 60 is raised by the height H by the elevating / rotating device 61 and then horizontally rotated, and the turntable is lowered to make the pins 64, 64
Positioning is performed by a, and the end of the core is fixedly held to the support member. Further, after the core is extracted from the cylindrical block body, as shown in FIGS. 3 and 4, the work of attaching the forming support 30 to the cylindrical block body in a skewered manner is performed, and In this case, the work of mounting the forming support can be performed with the turntable raised as necessary when the shaft of the forming support is attached to the cylindrical block body.

Further, both ends of the shaft of the molding support are fixed to the support members 51 and 56 of the drive / support member and the end support member, and the surface of the cylindrical block body is fixed using a cutting tool. When performing the cutting process, it is necessary to release the support of the cylindrical block body 20 by the clamp member and hold the cylindrical block body 20 so that the cylindrical block body can freely rotate. Further, when the turntable obstructs the movement of the cutting tool 70 during the cutting of the cylindrical block, an operation of lowering the turntable 60 to an arbitrary height is performed, which hinders the cutting by the cutting tool. Not to occur. Therefore, the turntable performs an up-and-down motion by the elevating / lowering device 61 at any time in accordance with the process of processing the cylindrical block body, and performs positioning corresponding to the processing of the cylindrical block body and the like, and the turntable alone. And the operation for moving up and down can be performed.

The drive / support member 50 and the end support member 5
A cutting tool device 70 arranged for performing cutting with a cutting tool on the cylindrical block body 20 held between the cutting tool 5 and the cutting tool 5 is configured as shown in FIG. Further, in this example, as described in FIGS. 3 to 5, the cylindrical block body 20 is supported by the forming support, and the cutting operation is performed while rotating through the shaft of the support.

In the cutting device 70, a vertical guide frame 74 is provided movably with respect to a horizontal guide frame 71 disposed on the frame 41 of the processing device, and is provided via a drive shaft 73 driven by a drive motor 72. The vertical guide frame 74 is moved. A bite support frame 76 is disposed on the vertical guide frame 74 via a rotating frame 75, and a bite support 77 is movably provided with respect to the bite support frame 76.
7 holds a byte 78. In the cutting tool 70, the work of positioning the cutting tool in the length direction of the cylindrical block body and processing both ends of the cylindrical block body into a tapered shape, and the cutting of the center of the cylindrical block body are optional. To be able to do. The cutting tool is configured in the same manner as a cutting tool such as a lathe generally used in the past, and the cutting tool has a cutting performance with respect to a plastic material such as polyethylene constituting a cylindrical block body. By using a blade member that can be satisfactorily performed, it is possible to perform a cutting operation in a good state without generating fine chips.

In cutting the cylindrical block body by the cutting tool, the bite depth and feed rate of the cutting tool suitable for cutting the plastic material are set in accordance with the processing of the plastic product. In this embodiment, a case is shown in which the positioning of the cutting tool 78 with respect to the cylindrical block body is performed manually. However, the machining operation of the cylindrical block body is configured as an apparatus that automatically performs all the operations, similarly to the NC lathe. It is possible to adopt a control method similar to that of a general lathe.
The processing apparatus having the above-described configuration is installed in a clean room, and each operating member is configured to protect dust, dust, and oil from scattering.

When forming the cylindrical block using the processing apparatus of the present invention having the above-described structure, the cylindrical block is held on a turntable as shown in FIG. The operation of extracting the core from both ends of the cylindrical block body is performed by the driving / supporting member. Then,
While holding the cylindrical block on the turntable,
A molding support having a configuration as shown in FIGS. 3 and 4 is attached, and both ends of a shaft of the molding support are driven and
After being held between the end support member 55 and the end support member 55, the turntable 60 is lowered to a position where it does not hinder the forming operation of the cylindrical block body. Then, while rotating the cylindrical block body using the rotating mechanism arranged on the driving / supporting member 50, the both ends of the cylindrical block body are tapered using the cutting tool 78 of the cutting tool 70. Also,
In the present invention, as shown in FIG. 5, when machining the tapered portions on both sides of the cylindrical block body, the cutting tool is difficult to machine the end of the cylindrical block body because the cutting tool comes into contact with the side flange 37. Therefore, in practice, the length of the cylindrical block body is made with a sufficient margin, and the tapered tip portion is machined to a position where the cutting tool does not contact the side flange, and the ring shape remaining on the side flange side is formed. Is cut off to form a reinforced insulator.

[0028]

As described above, by using the method for manufacturing a reinforced insulator according to the present invention, a cylindrical block is first cast and formed, and the cylindrical block is cut. Since a reinforcing insulator having an arbitrary outer shape can be manufactured, a reinforcing insulator having a shape required for a cable connection portion can be easily formed. Also, when removing the core from the cylindrical block, fix the cylindrical block on the turntable,
The core is locked to the driving / supporting member provided in the processing device, and the core is extracted. Thereafter, the other core is locked to the driving / supporting member to perform the extraction operation. The work of extracting the core can be easily performed without performing horizontal rotation or the like. Furthermore, the support for molding used to support the cylindrical block body during the cutting process holds and fixes both ends of the cylindrical block body using the end fixing members with respect to the shaft, so that the rotation of the shaft causes the eccentricity of the cylindrical block body. It does not cause rotation, and it is possible to easily cope with the cutting of the cylindrical block by the cutting tool.

The processing apparatus used for manufacturing the reinforcing insulator according to the present invention includes a turntable used for extracting a core from a cylindrical block body and for mounting a molding support and performing positioning corresponding to cutting. Since it is provided, it is possible to prepare for cutting without touching the cylindrical block body. Further, the processing apparatus imparts axial movement of the cylindrical block body and low-speed and high-speed rotation of the shaft to a driving / supporting member that supports one of the shafts mounted on the cylindrical block body. Since the mechanism is provided, it is possible to accurately perform the operation of applying low-speed rotation when the core is extracted from the cylindrical block body and the operation of performing high-speed rotation in cutting with a cutting tool.

[Brief description of the drawings]

FIG. 1 is an explanatory view of a casting method of a cylindrical block body.

FIG. 2 is an explanatory diagram of a method of extracting a core from a cylindrical block body.

FIG. 3 is an explanatory view showing a state in which a molding support is mounted on a cylindrical block body.

FIG. 4 is a sectional view of FIG. 3;

FIG. 5 is an explanatory view of a state where a cylindrical block body is cut.

FIG. 6 is a perspective view of a reinforcing insulator manufactured from a cylindrical block body.

FIG. 7 is a front view of a processing apparatus used for processing a cylindrical block body.

FIG. 8 is a plan view of the processing apparatus of FIG. 7;

FIG. 9 is an explanatory diagram of a turntable and a drive mechanism thereof.

FIG. 10 is a front view of the device of FIG. 9;

FIG. 11 is an explanatory diagram showing a relationship between a cylindrical block body and a cutting tool.

FIG. 12 is an explanatory diagram showing a configuration of a general cable connection unit.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Cable, 8 Cable connection part, 9 High voltage shield electrode, 10 Reinforcement insulator, 20 Cylindrical block body, 25 Die, 27 Core, 30
Molding support, 31 shaft, 32 end flange, 35 end fixing member, 40 processing device, 44 slide frame, 45 extraction device,
50 drive / support members, 51/56 support members,
55 end support members, 60 turntables, 6
1 Lifting / rotating device, 65 Clamp member, 7
0 byte device, 77 byte support, 78
Part-Time Job.

──────────────────────────────────────────────────続 き Continuation of the front page (56) References JP-A-8-98361 (JP, A) JP-A-8-182171 (JP, A) JP-A-8-182143 (JP, A) JP-A-8-182143 289434 (JP, A) (58) Fields investigated (Int. Cl. ⁷ , DB name) H02G 1/14 B29C 33/14 H01R 43/00 H02G 15/08

Claims (4)

(57) [Claims] 1. A step of positioning a core and a high-voltage shield electrode in a mold, injecting a plastic material to form a cylindrical block, extracting the cylindrical block from the mold and extracting the core. Mounting a molding support in accordance with the molding process; and supporting both ends of a shaft of the molding support on a rotating support member of a processing device, and cutting the cylindrical block body by a cutting tool provided in the processing device. A method for producing a reinforced insulator, comprising: a step of processing; 2. When the core is extracted from the cylindrical block, the cylindrical block is mounted on a turntable provided with a mechanism for fixing and holding the cylindrical block and a mechanism for vertically moving and rotating in the horizontal direction. After extracting one core, the vertical movement and horizontal rotation of the turntable are performed to change the position of the cylindrical block body, and then the other core is extracted, and the core is extracted. 2. The method according to claim 1, wherein a low-speed rotation is applied to the core. 3. A molding support disposed on a cylindrical block in accordance with a cutting process of the cylindrical block, comprising: a shaft inserted into a through hole of the cylindrical block; and a press from both sides of the cylindrical block. 3. An end fixing member having a side flange, and an end flange provided on both ends of the shaft and attached to a support member provided on a rotation support member of a processing apparatus, wherein: A method for manufacturing a reinforced insulator. 4. A processing apparatus for manufacturing the reinforcing insulator, wherein the turntable is provided with a mechanism for fixing and holding the cylindrical block, a mechanism for vertically moving and rotating in a horizontal direction, and is attached to the cylindrical block. A support member that holds both ends of the shaft of the molding support; a driving unit that imparts rotation to the one support member; an end support member that rotatably supports the other support member; A slide frame for supporting a support member provided with a means, a mechanism for moving the slide frame in the axial direction of the cylindrical block body, high-speed rotation means and low-speed rotation means for the support member disposed on the slide frame, and holding a cutting tool And a cutting tool provided with a guide means adapted to the cutting process.