KR102019138B1 - Face Cutting Apparatus and Face Cutting Method - Google Patents

Abstract

And a cutting portion having a rotating body portion, a fixed portion fixed to the rotating body portion, and a cutting edge portion protruding from the fixed portion toward the end face, wherein the cutting edge portion is formed at an end portion of the rotary body portion at a downstream side in the rotational direction of the sheet. It has a blade tip for cutting the cross section of the laminate, the blade tip is inclined with respect to the direction orthogonal to the side portion of the cutting blade portion, and with respect to the imaginary straight line perpendicular to the rotation axis and passing through the end portion close to the rotation axis of the blade end; Cross-section cutting device configured to be inclined to the downstream direction of rotation.

Description

Face Cutting Apparatus and Face Cutting Method

The present invention relates to a cross-sectional cutting device and a cross-sectional cutting processing method.

Cross Reference of Related Application

This application claims the priority of Japanese Patent Application No. 2016-249765 for which it applied on December 22, 2016, The content is integrated in description of this specification by reference.

Conventionally, sheets, such as a polarizing plate, are cut | disconnected and formed in predetermined shape and dimension one by one by the rotary blade etc. which have a blade part by outer periphery in a strip | belt-shaped sheet body, and are used for various uses.

Since the cross section of the sheet formed by such a cutting often has roughness due to the occurrence of burr or the pressure of the pressure-sensitive adhesive, a cross-section cutting device for cutting the cross section of the sheet has been proposed to remove them.

For example, a rotating body portion having a rotating shaft and rotating about the rotating shaft, and a cutting portion fixed to one surface of the rotating body portion to cut a cross section of a laminate in which sheets are stacked, the cutting portion being fixed to the rotating body portion A cross section cutting device having a fixed portion and a cutting edge portion protruding from the fixed portion toward the cross section of the laminate, the cutting edge portion having a blade tip for cutting the cross section at an end portion on the downstream side in the rotational direction of the rotary body portion is proposed. (Refer patent document 1). In this end face cutting apparatus, the edge of a cutting edge is formed along the direction orthogonal to the side part of a cutting edge part, and the whole cutting part inclines so that the rotational direction downstream of a cutting part (namely, a cutting edge part) may be located in the rotating shaft side, The blade tip is inclined toward the downstream side in the rotational direction with respect to the virtual straight line passing through the rotary shaft and the end portion close to the rotary shaft of the blade tip.

According to such a cutting device, the edge of the blade is inclined downward in the rotational direction with respect to the imaginary straight line, so that the cross section of the laminated body (laminated sheet) is cross-sectional cut while suppressing cracking or tearing of the sheet. It becomes possible.

Japanese Laid-Open Patent Publication No. 2011-93086

However, in the cross-section cutting device as described in Patent Document 1, when the cutting blade portion rotates in accordance with the rotation of the rotating body portion, the rotation direction upstream side (rear end side) of the cutting edge portion is an uncut region of the cross section of the laminate (sheet). As a result, there exists a possibility that surface cutting processing cannot fully be performed as a result.

In order to avoid contact with the uncut area of the cutting edge portion, it is conceivable to provide an inclined portion that is inclined in the direction falling from the end face toward the end portion opposite to the blade edge from the cutting edge portion at the cutting edge portion.

However, when the angle (inclined angle, radial rake angle) of such inclined portion is increased, there is a possibility that the strength of the cutting edge portion decreases by that amount.

In view of the above circumstances, it is an object of the present invention to provide a cross-section cutting device and a cross-section cutting method capable of suppressing cracks and cracks, relatively high strength of the cutting portion, and capable of sufficiently performing cross-sectional cutting. .

The cross-sectional cutting device according to the present invention,

A cross-section cutting device for cutting a cross section of a laminate in which sheets are laminated,

A rotating body part having a rotating shaft and rotating about the rotating shaft;

A cutting part fixed to one side of the rotating body part to cut the cross section;

The cutting portion has a fixed portion fixed to the rotating body portion, and a cutting blade portion protruding toward the cross section from the fixed portion,

The cutting blade portion has a blade tip for cutting the cross section at an end portion on the downstream side in the rotational direction of the rotating body portion,

The said blade tip is inclined with respect to the direction orthogonal to the side part of the said cutting blade part, and is comprised so that it may incline to the rotation direction downstream with respect to the imaginary straight line orthogonal to the said rotation axis, and passing through the edge part close to the said rotation axis.

In the end face cutting apparatus of the said structure,

It is preferable that the said cutting edge part is arrange | positioned inclined so that the edge part of the upstream of the rotation direction may be closer to the said rotation axis side than the edge of a downstream side with respect to the direction perpendicular | vertical to the said virtual straight line, or the direction perpendicular | vertical.

The cross-section cutting method according to the present invention,

As a cross-section cutting method of cutting the cross section of the laminated body in which sheets are laminated | stacked,

It is a method of cutting the said cross section by the said blade edge of the said cutting part which rotates the said cutting part by rotating the said rotary body part about the said rotating shaft using the said end surface cutting machine.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic side view which shows the cross-section cutting apparatus which concerns on embodiment of this invention.
FIG. 2 is a schematic plan view of the rotary body portion and the cutting edge portion periphery of the cross-sectional cutting machine of FIG.
FIG. 3 is a schematic front view showing a cutting blade portion provided in the cross-sectional cutting machine of FIG. 2. FIG.
It is a schematic side view which shows the state which the cutting edge part of FIG. 3 cuts the cross section of a laminated body (sheet) from the right side of FIG.
5 is a schematic plan view showing the rotational trajectory of the cutting edge portion of the present embodiment.
6 is a schematic plan view showing the rotational trajectory of the cutting edge portion of the present embodiment.
Fig. 7 is a schematic plan view of the cutting blade portion of which the blade edge extends along a direction perpendicular to the side edge portion of the cutting edge, the rotational trajectory of the cutting edge disposed on the rotating body so that the blade edge is inclined to the downstream side in the rotational direction with respect to the virtual straight line.

EMBODIMENT OF THE INVENTION Hereinafter, the cross-section cutting device which concerns on embodiment of this invention is demonstrated, referring drawings.

As shown in FIG. 1, FIG. 2, the cross-section cutting device 1 of this embodiment is

As the cross-section cutting device 1 which cuts the end surface 60a (namely, the end surface 50a of the laminated sheet 50) by which the sheet | seat 50 is laminated | stacked,

A rotating body portion 11 having a rotating shaft R and rotating about the rotating shaft R;

It is provided with the cutting part 21 which is fixed to the one surface 11a of the said rotating body part 11, and cuts the said end surface 60a (end surface 50a),

The cutting portion 21 is a fixed portion 23 fixed to the rotating body portion 11, and a cutting edge portion 25 protruding from the fixed portion 23 toward the end face 60a (cross section 50a). ),

The cutting edge portion 25 has a blade tip 27 for cutting the end face 60a (cross section 50a) at an end portion downstream of the rotation direction M of the rotating body portion 11,

The blade tip 27 is inclined with respect to the direction N orthogonal to the side surface portion 25a of the cutting blade portion 25, and is orthogonal to the rotation shaft R and the rotation shaft R of the blade tip 27. It is comprised so that it may incline to the downstream side of the said rotation direction M with respect to the virtual straight line L1 passing through the near edge part 27a.

The end face cutting device 1 is capable of rotating the rotating body 11, and the support part 31 which is movable so that the cutting part 21 to support cuts the whole end surface 60a (cross section 50a), and And a driving part 33 for rotationally driving the rotating body part 11, and a holding part 35 for holding the laminated body 60 (laminated sheet 50) sandwiched between the lowermost side and the uppermost side. Equipped.

In addition, the downstream side of the rotation direction M means the front side (advancing side) of the rotation direction M, and the upstream side of the rotation direction M means the back side (opposite side to a progress direction) of the rotation direction M. As shown in FIG. .

Although the sheet 50 is not specifically limited, For example, a polarizing plate is mentioned. As this polarizing plate, what the polarizer laminated with the protective film via the adhesive is mentioned.

The shape of the sheet 50 is rectangular shape, for example.

The quantity of the sheet | seat 50 laminated is not specifically limited.

The rotating body portion 11 rotates to impart cutting force to the blade tip 27 of the cutting edge portion 25 of the cutting portion 21.

The shape, material, size, etc. of the rotating body part 11 are not specifically limited.

For example, the shape of the rotating body part 11 is disk shape, and the rotating body part 11 is formed of metal materials, such as stainless steel.

The size of the rotating body portion 11 may be appropriately set depending on the quantity of the sheet 50 to be laminated and the like.

The rotating body part 11 is comprised so that a movement to the direction of the rotation axis R and the direction perpendicular | vertical to the rotation axis R is possible with the movement of the support part 31. FIG.

The rotating body part 11 is rotatably supported by the support shaft 32 arrange | positioned at the support part 31. As shown in FIG.

In the embodiment shown in FIG. 1 and FIG. 2, the rotating body portion 11 has a recessed portion 12 indented inward from the outer circumference of the rotating body portion 11 so that the cutting portion 21 is fitted into the fitting portion.

The quantity of the rotating body part 11 is not specifically limited. Even if one rotating body part 11 is provided so that one end surface 60a (one end surface 50a of the laminated sheet 50) of the laminated body 60 can be cut, Two end faces 60a (two end faces 50a) may be provided so that they can be cut at one time.

The rotational speed of the rotor 11 is not particularly limited, but may be, for example, 1000 to 6000 rpm.

The cutting portion 21 is fixed to one surface 11a of the rotating body portion 11 to cut the end face 60 (end surface 50a).

1 and 2 show an embodiment in which six cutting portions 21 are arranged on the rotating body portion 11, but the number of cutting portions 21 disposed on the rotating body portion 11 is not particularly limited.

The cutting part 21 is a fixed part 23 fixed to the rotating body part 11, and the cutting which protrudes more than the rotating body part 11 toward the end surface 60a (cross section 50a) from the said fixing part 23. It has the blade part 25.

The fixed part 23 is orthogonal to the rotation axis R, and extends along the direction P perpendicular to the virtual straight line L1 passing through the end portion 27a close to the rotation axis R of the blade tip 27. Moreover, the virtual straight line L1 is on one side 11a of the rotating body part 11 (as parallel with one side 11a of the rotating body part 11), and the rotation axis R and the blade edge 27 It is an imaginary straight line passing through the end portion 27a close to the rotation axis R. FIG.

The fixing part 23 is formed in rectangular shape when it sees along the extension direction of the rotating shaft R. As shown in FIG.

The fixing part 23 is fitted in the recessed part 12 formed in the rotating body part 11, for example, and is being fixed. In the aspect of FIG. 1 and FIG. 2, it fits in the recessed part 12 of the rotating body part 11, and is comprised so that it may be fixed by fixing members 23a, such as a screw.

The arrangement on the rotating body portion 11 of this fixing portion 23 is such that the arrangement of the cutting edge portion 25 is determined.

The cutting edge portion 25 cuts the end surface 60a of the laminated body 60 (end surface 50a of the laminated sheet 50).

The cutting blade portion 25 protrudes from the fixed portion 23 on the side opposite to the rotary body portion 11, and has a blade tip 27 at an end portion on the downstream side of the rotation direction M of the rotary body portion 11. have.

The cutting edge portion 25 is formed in a rectangular shape when viewed along the extending direction of the rotation shaft R, and has a side portion 25a close to the rotation shaft R and a side portion 25b far from the rotation shaft R. As shown in FIG.

The blade edge | tip 27 is formed so that the cross section 60a (cross section 50a of the laminated sheet 50) of the laminated body 60 may be cut.

The blade tip 27 is inclined with respect to the direction N orthogonal to the side surface portion 25a of the cutting blade portion 25.

The blade tip 27 is inclined to the downstream side of the rotation direction M with respect to the virtual straight line L1 in a state where the fixing portion 23 is fixed to the rotating body portion 11 (end portion 27a close to the rotation shaft R). ), So that the end 27b farther from the rotation shaft R is inclined so as to be located downstream of the rotation direction M.

In the present embodiment, the cutting edge portion 25 is formed integrally with the fixed portion 23, but may be formed separately from the fixed portion 23.

Although the angle (theta) 1 which the blade edge | tip 27 makes with respect to the virtual straight line L1 is not specifically limited, It is more than 0 degree and 20 degrees or less (0 degree <(theta) <1 <20 degree) is preferable.

In addition, the angle (angle on the imaginary plane including the rotation direction M) (theta) 2 which the blade edge | tip 27 makes with respect to the said orthogonal direction N is not specifically limited, but is 15 degree exceeding 0 degree. The following is preferable (0 ° <θ2≤15 °).

The material of the cutting edge part 25 is not specifically limited. As the material, carbon steel (S45C) etc. are mentioned, for example.

The material of the blade tip 27 is not particularly limited as long as the end face 60a (end face 50a) can be cut. For example, the blade tip 27 may have a diamond crystal layer on the outermost surface of the carbon steel (S45C). As a particle diameter of such a diamond particle, 5-50 micrometers is mentioned, for example.

The shape of the blade tip 27 is not particularly limited. For example, when the blade tip 27 is viewed along the extending direction of the rotation shaft R, the blade tip 27 may be curved as if it protrudes toward the downstream side of the rotation direction M.

When it is curved, it is preferable that the radius of curvature is 1 to 50% with respect to the distance which connects the rotating shaft R and the edge part 27a near the rotating shaft R of the blade edge | tip 27 at the shortest.

In the present embodiment, the cutting edge portion 25a is inclined portion 26a inclined in the direction falling from the end face 60 (cross section 50a) toward the edge portion of the blade edge 27 on the side opposite to the blade edge 27. 26b).

Since the cutting edge portion 25 has the inclined portions 26a and 26b, the cutting edge portion 25 can be further suppressed from contacting the uncut region of the end face 60a (the end face 50a).

Angle of inclination of the inclined part 26a closest to the blade tip 27 among the inclined parts 26a and 26b (the first conduction angle, which is made with respect to the imaginary plane including the rotation direction M). θ3 may be, for example, greater than 0 ° and less than or equal to 15 ° (0 ° <θ3 ≦ 15 °).

The inclination angle of the inclination portion 26b (the angle formed with respect to the imaginary plane including the rotation direction M as the second conduction angle) can be appropriately set.

Further, the inclination angle (tilt angle) of the blade tip 27 with respect to the imaginary plane including the rotation direction M may be greater than 0 ° and 20 ° or less (0 ° <inclination angle ≤ 20 °).

In addition, in this invention, the aspect in which the cutting edge part 25 does not have inclination part 26a, 26b may be employ | adopted.

The arrangement of the cutting portion 21 in the rotating body portion 11 is such that the blade tip 27 is inclined to the downstream side in the rotational direction with respect to the virtual straight line L1 while the fixing portion 23 is fixed to the rotating body portion 11. Arrangement may be sufficient and it is not specifically limited.

For example, in the aspect shown in FIG. 2, the cutting edge part 25 (namely, the cutting part 21) is the direction P perpendicular | vertical to the virtual straight line L1 on one side 11a of the rotating body part 11. As shown in FIG. It is arranged along.

In this case, when the rotating body part 11 rotates, as shown in FIG. 5, the cutting edge part 27 of the cutting edge part 25 passes through the area | region which passes through, ie, the side of the rotation axis R (the side closest to the rotation axis R). Cross section in the region between the rotational trace D1 of the end 27a of the end) and the rotational trace D2 of the end 27b of the side opposite the most rotational axis R (side away from the rotational axis R). (60a (cross section 50a)) is cut out.

At this time, the part corresponding to the diagonal with respect to the edge part 27a in the cutting edge part 25 (namely, the part which is the upstream side of the rotation direction M of the cutting edge part 25, and is the part which is furthest from the edge part 27a). The rotational trajectory D3 of) is substantially coincident with the rotational trajectory D2 of the end portion 27b far from the rotation axis R of the blade tip 27 described above. That is, the rotational trace D3 does not push outward from the rotational trace D2 of the end portion 27b.

Therefore, contact with the uncut area (the area on the right side of the rotation trajectory D2 in FIG. 5) is suppressed.

For example, as shown in FIG. 6, the cutting part 21 of the rotation direction M of the cutting edge part 25 (namely, the cutting part 21) with respect to the direction P perpendicular | vertical to the virtual straight line L1. You may arrange | position inclined so that the edge part of an upstream may become closer to the rotating shaft R than the edge part of a downstream side.

Also in this case, when the rotating body part 11 rotates, as shown in FIG. 6, the cutting edge part 27 of the cutting edge part 25 passes through the area | region which passes through, ie, the rotation axis R side (close to the rotation axis R). The area between the rotational trace D1 of the end 27a of the side) and the rotational trace D2 of the end 27b of the side (the side away from the rotational shaft R) opposite to the rotational axis R most. The end surface 60a (end surface 50a) is cut | disconnected in the process.

At this time, the rotational trace D3 of the part corresponding to the diagonal with respect to the edge part 27a in the cutting edge part 25 is the rotational trace D2 of the edge part 27b which is far from the rotation axis R of the said blade tip 27. It becomes smaller than). Specifically, the rotation trajectory D3 of the portion corresponding to the diagonal with respect to the end 27a of the cutting edge portion 25 is the rotation trajectory D2 of the end 27b far from the rotation axis R of the blade tip 27 described above. ) And larger than the rotational trace D1 of the end portion 27a close to the rotational axis R of the blade tip 27. That is, the rotational trace D3 does not push outward from the rotational trace D2 of the end portion 27b.

Therefore, contact with the uncut area (the area on the right side of the rotation trajectory D2 in FIG. 6) is suppressed.

On the other hand, as shown in FIG. 7, when the blade tip 27 is formed along the direction N orthogonal to the side part 25a of the cutting blade part 25, the blade tip 27 is attached to the said virtual straight line L1. In order to incline to the downstream side of the rotation direction M with respect to the cutting edge part 25 (namely, the cutting part 21), the edge part of the downstream side of the rotation direction M of the said cutting edge part 25 is the upstream side. It is necessary to incline so that it may be located closer to the rotating shaft R than an edge part.

In this case, the rotational trajectory D3 of the portion corresponding to the diagonal with respect to the end 27a in the cutting edge portion 25 is the rotational trajectory of the end 27b far from the rotation axis R of the blade tip 27 described above. Larger than D2). That is, the rotational trace D3 is pushed outward from the rotational trace D2 of the end portion 27b.

Therefore, the part of the cutting edge part 25 which protruded more than the rotation trace D2 of the edge part 27b far from the rotation axis R of the blade tip 27 has an uncut area | region (right side than the rotation trace D2 in FIG. 7), As a result, a problem arises easily in the end surface 60a (end surface 50a) by end surface cutting.

However, as mentioned above, in the aspect of FIG. 5 and FIG. 6, the radius of the rotation trace D3 becomes equal to or smaller than the radius of the rotation trace D2. Therefore, the aspect of FIG. 5 and FIG. 6 can suppress that the cutting edge part 25 contacts the uncut area | region of end surface 60a (cross section 50a) rather than the aspect of FIG.

The support part 31 is comprised so that a movement is possible in parallel with the plane containing the rotation direction M of the rotating body part 11, and along the direction perpendicular | vertical to the plane. The support part 31 is made to be moved by the conventionally well-known moving apparatus, for example.

By moving the support part 31 in the parallel direction, the whole can be cut from one end to the other end of the end face 60a (the end face 50a), and the end face 60a of the blade tip 27 moves in the vertical direction. It is comprised so that the cutting depth with respect to (section 50a) may be adjusted.

The drive part 33 rotates the rotating body part 11. As the drive part 33, a motor is mentioned, for example.

The holding part 35 sandwiches and holds the laminated body 60 (laminated sheet 50) from the lowermost side and the uppermost side. The holding | maintenance part 35 is laminated body 60 (laminated sheet 50). The first and second portions 35a and 35b in contact with the uppermost surface, and are sandwiched by these first and second portions 35a and 35b. The stacked sheet 50) is held in. The holding unit 35 connects the virtual straight line L2 that connects the center of the bottom surface of the laminate 60 (the laminated sheet 50) with the center of the uppermost surface. It rotates about (refer FIG. 1), and can change the cross section 60a (cross section 50a) which is cross-sectional-processed in the laminated body 60 (stacked sheet 50).

Next, the operation | movement of the cross-section cutting device 1 of this embodiment is demonstrated.

When the support part 31 is moved and the rotor part 11 is rotated by the drive part 33, the end surface 60a (lamination | lamination) which opposes the rotor part 11 of the laminated body 60 (laminated sheet 50) is laminated. The sheet 50)) is cut by the blade tip 27 of the cutting blade portion 25 of the cutting portion 21 from one end to the other end thereof.

As mentioned above, the cross-section cutting device 1 of this embodiment is

As a cross-section cutting apparatus 1 which cuts the end surface 60a (cross-section 50a of the laminated sheet 50) of the laminated body 60 by which the sheet | seat 50 is laminated | stacked,

A rotating body portion 11 having a rotating shaft R and rotating about the rotating shaft R;

It is provided with the cutting part 21 which is fixed to the one surface 11a of the said rotating body part 11, and cuts the said end surface 60a (end surface 50a),

The cutting portion 21 is a fixed portion 23 fixed to the rotating body portion 11, and a cutting edge portion 25 protruding from the fixed portion 23 toward the end face 60a (cross section 50a). ),

The cutting edge portion 25 has a blade tip 27 for cutting the end face 60a (cross section 50a) at an end portion downstream of the rotation direction M of the rotating body portion 11,

The blade tip 27 is inclined with respect to the direction N orthogonal to the side surface portion 25a of the cutting blade portion 25 and is orthogonal to the rotation axis R and the rotation shaft R of the blade tip 27. It is comprised so that it may incline to the downstream side of the said rotation direction M with respect to the virtual straight line L1 passing through the near edge part 27a.

According to the cross-sectional cutting apparatus 1 of this embodiment, it is extended along the said virtual straight line L1 by making the blade edge | tip 27 incline to the downstream side of the rotation direction M with respect to the said virtual straight line L1. It can suppress that a crack and a crack generate | occur | produce in the sheet | seat 50 at the time of end surface cutting rather than a case.

As described above, as shown in FIG. 7, in the case of using the cutting edge portion 25 in which the blade tip 27 is formed along the direction N orthogonal to the side surface portion 25a of the cutting edge portion 25. In order to incline the blade edge 27 to the downstream side of the rotation direction M with respect to the virtual straight line L1, it is necessary to incline the entire cutting part 21. However, in this case, when the cutting blade portion 25 rotates along the rotation of the rotating body portion 11, the portion corresponding to the diagonal with respect to the end portion 27a close to the rotating shaft R in the cutting blade portion 25 (cutting) As the upstream side of the rotational direction M of the blade part 25, the radius of the rotational trace D3 which the part which is furthest from the edge part 27a closest to the said rotating shaft R is the rotation axis R of the blade edge | tip 27 It becomes larger than the radius of the rotational trace D2 which the edge part 27b far from () draws. For this reason, the part of the said upstream side of the cutting edge part 25 which protruded outward from the rotation trace D2 of the blade edge | tip 27 is the end surface 60a of the laminated body 60 (cross section 50a of the laminated sheet 50). It comes into contact with the uncut area of))), and as a result, there is a possibility of causing a problem in end face cutting.

On the contrary, as in the present embodiment, the blade tip 27 is inclined with respect to the direction N orthogonal to the side surface portion 25a of the cutting edge portion 25, and the rotational direction M with respect to the virtual straight line L1. By inclining on the downstream side, it is possible to incline the blade edge 27 relatively largely downstream of the rotation direction M by inclining relatively small even when the inclined portion 21 is not inclined and even when inclined. do. For this reason, it is suppressed that the cutting edge part 25 contacts with an uncut area by that much. In addition, it is not necessary to provide the inclined portions 26a and 26b on the cutting edge portion 25 as described above, or even when the inclined portions 26a and 26b are provided, the inclination angle θ3 can be made relatively small. Therefore, the strength of the cutting edge portion 25 is relatively large.

Therefore, cracks and cracks can be suppressed, the intensity | strength of the cutting part 21 is comparatively high, and it becomes possible to fully perform end surface cutting.

In the cross-section cutting device 1 of this embodiment,

The cutting edge portion 25 is along the direction P perpendicular to the virtual straight line L1, or the upstream end portion of the rotation direction M with respect to the vertical direction P is smaller than the downstream end portion. It is preferable that it is comprised so that it may be inclined so as to become close to R side.

According to such a structure, since the rotational trace D3 of the part corresponding to a diagonal can be made smaller with respect to the edge part 27a which is close to the said rotating shaft R in the cutting blade part 25, the cutting blade part 25 is The contact with the uncut area of the end surface 60a (end surface 50a of the laminated sheet 50) of the laminated body 60 can be suppressed more. Therefore, it becomes possible to perform cross section processing more fully.

The cross-section cutting method of the present embodiment,

As a cross-sectional cutting processing method which cuts the end surface 60a (cross-section 50a of the laminated sheet 50) of the laminated body 60 by which the sheet | seat 50 is laminated | stacked,

The blade tip of the cutting portion 21 is rotated while rotating the cutting portion 21 by rotating the rotary body portion 11 about the rotation axis R using the cross-sectional cutting device 1. (27) is a method of cutting the end face 60a (end face 50a).

According to such a structure, by performing a cross-sectional cutting process using the said cross-section cutting device 1, a crack and a crack can be suppressed as mentioned above, the intensity | strength of the cutting part 21 is comparatively high, and also the cross-sectional cutting process It becomes possible to implement this sufficiently.

As mentioned above, according to this embodiment, the crack and the crack can be suppressed, the strength of the cutting part 21 is comparatively high, and the cross-section cutting apparatus 1 and cross-sectional cutting which can fully perform a cross-sectional cutting process are also possible. A method is provided.

As mentioned above, although embodiment and Example of this invention were described, it is planned from the beginning to combine suitably the characteristic of each embodiment and Example. In addition, it should be thought that embodiment and Example which were disclosed this time are an illustration in all respects, and are not restrictive. The scope of the present invention is shown not by the above-described embodiments and examples but by the claims, and is intended to include any modifications within the scope and meaning equivalent to the claims.

1: face cutting device
11: rotating body part
11a: one side
21: cutting part
23: fixing part
25 cutting edge portion
27: the end of the blade
27a, 27b: end
31: support
33: drive unit
35: holding part
50: sheet
50a: cross section
60: laminated body, cross section 60a

Claims (8)

A cross-section cutting device for cutting a cross section of a laminate in which sheets are laminated,
A rotating body part having a rotating shaft and rotating about the rotating shaft;
A cutting part fixed to one side of the rotating body part to cut the cross section;
The cutting portion has a fixed portion fixed to the rotating body portion, a cutting blade portion protruding from the fixed portion toward the cross section,
The cutting blade portion has a blade tip for cutting the cross section at an end portion on the downstream side in the rotational direction of the rotating body portion,
The blade tip is inclined with respect to the direction orthogonal to the side surface portion of the cutting blade portion, and the end portion away from the rotation axis of the blade tip with respect to the imaginary straight line perpendicular to the rotation axis and passing through the end portion close to the rotation axis of the blade tip with the rotation shaft. It is inclined so that it may be located in the downstream direction of rotation rather than the near end,
The side cutting part of the said cutting blade part is extended so that it may extend along the direction perpendicular | vertical to the said virtual straight line, viewed in the axial direction of the said rotating shaft. The method of claim 1,
And the cutting edge portion is disposed to be inclined along the direction perpendicular to the virtual straight line, or inclined so that the end side of the upstream side in the rotational direction is closer to the rotation axis side than the downstream end side with respect to the vertical direction. As a cross-section cutting method of cutting the cross section of the laminated body in which sheets are laminated | stacked,
The cross section cutting method of cutting the said cross section by the said blade edge part of the said cutting part which rotates the said cutting part by rotating the said rotating body part about the said rotating shaft using the cross-sectional cutting machine of Claim 1. As a cross-section cutting method of cutting the cross section of the laminated body in which sheets are laminated | stacked,
The cross section cutting method of cutting the said cross section by the said blade edge of the said cutting part which rotates the said cutting part by rotating the said rotary body part about the said rotating shaft using the cross-section cutting device of Claim 2. The method of claim 1,
An end face cutting device in which the blade end faces the end face in an extension direction of the rotation shaft. The method of claim 2,
An end face cutting device in which the blade end faces the end face in an extension direction of the rotation shaft. As a cross-section cutting method of cutting the cross section of the laminated body in which sheets are laminated | stacked,
The cross section cutting method of cutting the said cross section by the said blade edge of the said cutting part which rotates the said cutting part by rotating the said rotating body part about the said rotating shaft using the cross-sectional cutting machine of Claim 5. As a cross-section cutting method of cutting the cross section of the laminated body in which sheets are laminated | stacked,
The cross section cutting method of cutting the said cross section by the said blade edge of the said cutting part which rotates the said cutting part by rotating the said rotating body part about the said rotating shaft using the cross-sectional cutting machine of Claim 6.

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