JP2006044042A - Cutter attaching device of processing machine - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a cutter attaching device constituted so as to attach a circular rotary cutter to the spindle of a processing machine, capable of using a cutter corresponding to a commercial product as the rotary cutter and having high general-purpose properties. <P>SOLUTION: The cutter S1 is held between the inclined attaching surface 11K of an inner flange 11 in a first flange pair P1 and the inclined attaching surface 12K of the outer flange 12 in the first flange pair P1 and the cutter S2 is held between the inclined attaching surface 13K of the inner flange 13 in a second flange part P2 and the inclined attaching surface 14K of the outer flange 14 in the second flange part P2. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a blade attachment device for attaching a circular blade to a spindle in a processing machine such as a grooving machine used for grooving for forming a groove portion along a longitudinal direction of wood, for example. In this specification, a cutting tool refers to a general circular cutting tool used for cutting, such as a chip saw or a diamond cutter.

For example, as disclosed in Japanese Patent Application Laid-Open No. 57-169301, a groove having a constant width can be formed along the longitudinal direction of the wood by tilting and attaching a circular cutting tool to the spindle. .
Further, as disclosed in, for example, Japanese Patent Publication No. 59-1561, the width of the groove to be formed can be changed by making the inclination angle of the cutting tool relative to the spindle adjustable. When the inclination angle of the cutting tool with respect to the spindle is increased, the groove width formed is increased. Conversely, when the inclination angle is decreased, the groove width is decreased.
Further, as disclosed in Japanese Examined Patent Publication No. 7-4801, a groove having a large width can be formed by attaching two blades to the spindle while being inclined in opposite directions.
JP-A-57-169301 Japanese Patent Publication No. 7-4801 Japanese Patent Publication No.59-1561

Thus, conventionally, there has been provided a grooving machine capable of grooving with a constant width by attaching the cutting tool to the spindle while inclining the circular cutting tool.
However, these conventional grooving machines each have a configuration that requires a dedicated cutting tool having a special form (specification), and it is difficult to use a commercially available cutting tool.
The present invention has been made in view of this problem, and is an apparatus for attaching a circular rotary blade to a spindle of a processing machine, and provides a highly versatile blade attachment device capable of diverting a blade equivalent to a commercially available product. With the goal.

For this reason, this invention was set as the blade attachment apparatus of the structure described in each claim of a claim.
According to the cutting tool mounting apparatus according to claim 1, the single cutting tool is sandwiched between the inclined mounting surface of the inner flange and the inclined mounting surface of the outer flange, so that the mounting tool is tilted with respect to the rotation axis of the spindle. Therefore, a commercially available general-purpose type cutting tool can be attached in an inclined state with respect to the spindle.
According to the blade attachment device of the second aspect, the inner flange and the outer flange are positioned in the rotational direction with respect to each other by the first positioning portion. Therefore, it is possible to easily align the both flanges in the rotational direction. As a result, the assemblability can be improved, and the shift in the rotational direction between the flanges during operation can be prevented.
According to the blade mounting apparatus of claim 3, when the blade is sandwiched between the inclined mounting surfaces of the inner flange and the outer flange and the both positioning flanges are positioned in the rotational direction by the first positioning portion, the first positioning is performed. Since the blade is also positioned in the rotational direction with respect to both flanges by the portion, the attachment of the blade can be improved.
According to the blade attachment device of claim 4, since two general-purpose type blades can be attached to the spindle in an inclined state, it is possible to cope with cutting of a wider groove, thereby cutting form The variation of can be increased.
According to the blade attachment device of claim 5, the blade is inclined by placing the two blade tools in plane symmetry (hereinafter the same) with respect to the inclination direction and the inclination angle with respect to the orthogonal attachment surface orthogonal to the rotation axis of the spindle. Since the vibrations generated by canceling each other are canceled out, a quick and smooth cutting process (grooving process) can be performed. Also, by providing a second positioning portion for positioning the two pairs of flanges in the rotational direction, the two flanges can be easily aligned with each other, and the assemblability can be improved. A shift in the rotation direction can be prevented.
According to the blade attachment device of claim 6, a part of the second positioning part that makes the two blades relatively non-rotatable, a part of the first positioning part that makes the inner flange and the outer flange non-rotatable. This also makes it possible to simplify the structure and reduce costs.

Next, an embodiment of the present invention will be described with reference to FIGS. In this embodiment, a so-called grooving machine is illustrated as an example of a processing machine. The present invention is characterized by the blade attaching device of this grooving machine, and the configuration other than the blade attaching device such as the processing machine main body is the same as that of the conventional grooving machine. Since no change is required, the description and illustration thereof are omitted.
FIG. 1 shows a blade attachment device 10 according to the present embodiment. Reference numeral 1 in the figure indicates a spindle of the grooving machine. The spindle 1 is rotated by an electric motor built in the grooving machine body. The blade attachment device 10 of this example is attached to the spindle 1. Two blades B1 and B2 are attached to the spindle 1 via the blade attachment device 10.
The spindle 1 includes a flange portion 1a, a boss portion 1b, and a male screw portion 1c. Flat surfaces 1d and 1d are formed on the circumferential surface of the boss portion 1b at bisected positions in the circumferential direction. A fixing nut 2 is fastened to the male screw portion 1c. The blade attachment device 10 of this example described below is fixed in a state of being sandwiched between the boss portion 1b (or flange portion 1a) and the fixing nut 1c.
The blade attachment device 10 includes two sets of flange pairs (a first flange pair P1 and a second flange pair P2). Both flange pairs P1, P2 are provided with inner flanges 11, 13 and outer flanges 12, 14, respectively. Inner flanges 11 and 13 in both flange pairs P1 and P2 have the same shape. Moreover, the outer flanges 12 and 14 in both flange pairs P1 and P2 have the same shape. Accordingly, both flange pairs P1, P2 have the same configuration. Hereinafter, the inner flange 11 and the outer flange 12 of the left first flange pair P1 in FIG. 1 will be described.

2 and 3 show the inner flange 11 of the first flange pair P1 alone, and FIGS. 4 and 5 similarly show the outer flange 12 of the first flange pair P1 alone. The inner flange 11 has a mounting hole 11a for inserting the spindle 1 at the center thereof. The end face on the left side of the inner flange 11 in the figure is an orthogonal mounting surface 11T that is orthogonal to the axis of the mounting hole 11a (the rotational axis L of the spindle 1). Further, the right end face of the inner flange 11 in the figure is an inclined mounting surface 11K that is inclined at an angle θ with respect to the orthogonal mounting surface 11T. The attachment hole 11a penetrates from the orthogonal attachment surface 11T to the inclined attachment surface 11K.
In the center of the orthogonal mounting surface 11T, a recess 11b into which the boss 1b of the spindle 1 can be inserted is formed coaxially with the mounting hole 11a. Although not shown, a flat surface that protrudes inward is formed on the inner peripheral side of the recess 11b in correspondence with the flat surfaces 1d and 1d of the boss 1b of the spindle 1. Moreover, as shown in FIG. 1, this recessed part 11b is formed in the depth which makes a part approach in the height direction of the boss | hub part 1b. For this reason, a gap substantially corresponding to the plate thickness of the blade B1 (B2) is formed between the inner flange 11 and the flange portion 1a of the spindle 1. When the first flange pair P1 is mounted on the spindle 1 with the boss 1b entering the recess 11b, the inner flange 11 is fixed to the spindle 1 in the rotational direction without rattling.
Positioning pins 11c and 11d are projected in parallel with the axis L of the spindle 1 on the orthogonal mounting surface 11T and the inclined mounting surface 11K, respectively. Both the positioning pins 11c and 11d have the same diameter, and are arranged at bisected positions in the circumferential direction. Further, the positioning pins 11c and 11d are arranged at an equal distance from the axis L. Further, the positioning pin 11c on the orthogonal mounting surface 11T side is disposed at a position where the plate thickness of the inner flange 11 is the largest, and the positioning on the inclined mounting surface 11K side is the position of the positioning pins 11c and 11d around the axis L. The pin 11d is disposed at a portion where the thickness of the inner flange 11 is the smallest.
A boss portion 11e is formed at the center of the inclined mounting surface 11K of the inner flange 11. The boss portion 11 e is formed with the same diameter as the boss portion 1 b of the spindle 1. The height of the boss portion 11e from the inclined mounting surface 11K is set to a dimension slightly smaller than the plate thickness of the blade B1 (B2). The central axis L1 of the boss portion 11e is inclined by an angle θ with respect to the axis of the mounting hole 11a (the axis L of the spindle 1). Therefore, the boss portion 11e (its axis L1) is orthogonal to the inclined mounting surface 11K. The boss 11e is also formed with an attachment hole 11a penetrating along the axis L.
Further, as shown in FIG. 3, flat surfaces 11f and 11f similar to the boss portion 1b of the spindle 1 are formed at the bisected position of the peripheral surface of the boss portion 11e.

Next, as shown in FIGS. 4 and 5, the outer flange 12 includes a mounting hole 12 a for inserting the spindle 1 at the center thereof. The attachment hole 12 a is formed coaxially and with the same diameter as the attachment hole 11 a of the inner flange 11. An end face on the right side of the outer flange 12 in the figure is an orthogonal attachment surface 12T orthogonal to the axis L of the attachment hole 12a. The left end face of the outer flange 12 in the figure is an inclined mounting surface 12K that is inclined at an angle θ with respect to the orthogonal mounting surface 12T. For this reason, in a state in which both flanges 11 and 12 are mounted on the spindle 1, the inclined mounting surface 12 </ b> K of the outer flange 12 is disposed in parallel to the inclined mounting surface 11 </ b> K of the inner flange 11.
The mounting hole 12a of the outer flange 12 also penetrates from the orthogonal mounting surface 12T to the inclined mounting surface 12K.
A boss portion 12b is formed at the center of the orthogonal mounting surface 12T of the outer flange 12. The axis of the boss portion 12b coincides with the axis L. The boss portion 12 b is formed with the same diameter and height as the boss portion 11 e of the inner flange 11. Flat surfaces 12d and 12d are also formed at the bisected position of the peripheral surface of the boss portion 12b.
Further, a positioning hole 12c is formed at a portion where the plate thickness of the outer flange 12 is the largest. The positioning hole 12c is formed to penetrate from the inclined mounting surface 12K to the orthogonal mounting surface 12T. The positioning hole 12c is formed at a position and a diameter where the positioning pins 11c and 11d of the inner flange 11 can be inserted. Further, as shown in FIG. 5, the positioning hole 12 c is formed in a groove shape that is slightly longer in the radial direction of the outer flange 12.
A first flange pair P1 composed of the inner flange 11 and the outer flange 12 formed in this way and a second flange pair P2 configured in the same manner are mounted adjacent to the spindle 1. Both flange pairs P1 and P2 are attached to the spindle 1 in a non-rotatable manner by firmly fastening the fixing nut 2 to the male screw portion 1c. In this mounted state, the flange pairs P1 and P2 are sandwiched between the flange portion 1b and the fixing nut 2 in the order of the inner flange 11, the outer flange 12, the inner flange 13, and the outer flange 14 from left to right in FIG. ing.
A cutting tool (hereinafter referred to as a first cutting tool B1) is sandwiched between the inner flange 11 and the outer flange 12 of the first flange pair P1, and a cutting tool (between the inner flange 13 and the outer flange 14 of the second flange pair P2). Hereinafter, the second cutting tool B2) is attached in a state where it is sandwiched.

FIG. 6 shows a state in which two cutting tools (the first cutting tool B1 and the second cutting tool B2) are substantially superimposed concentrically. The first cutting tool B1 and the second cutting tool B2 are circular so-called tip saws having the same thickness, and each has 19 tips (blade edges) at equal intervals around the tip. Hereinafter, the tips of the blades B1 and B2 are referred to as blade edges B1c to B1c and B2c to B2c.
Both cutting tools B1 and B2 are provided with mounting holes B1a and B2a and positioning holes B1b and B2b. Each attachment hole B1a, B2a is formed with the same diameter. These mounting holes B1a and B2a are the same as the mounting holes that are usually commercially available, and can be used as they are without any additional processing. Both mounting holes B1a and B2a are formed with an inner diameter that allows the boss portion 11e of the inner flange 11 and the boss portion 12b of the outer flange 12 to be inserted without rattling. Since the mounting holes B1a, B2a are formed as circular holes, the flat surfaces 11f, 11f, 12d, 12d of the boss portions 11e, 12b rotate with respect to the mounting holes B1a, B2a of the cutting tools B1, B2. Stop function is not demonstrated.
The positioning holes B1b and B2b are formed in the same manner as the positioning holes 12c and 14c of the outer flanges 12 and 14 with respect to the distance and shape from the center (axis line L). That is, the positioning holes B1b and B2b are formed as long slot holes that are slightly longer in the radial direction.
The first cutting tool B1 and the second cutting tool B2 are different from each other with respect to the circumferential positions of the cutting edges B1c, B2c and the positioning holes B1b, B2b. That is, as shown in FIG. 6, when the two positioning tools B1 and B2 are overlapped with the mutual positioning holes B1b and B2b shifted by 180 ° in the circumferential direction, the second between the two cutting edges B1c and B1c adjacent to the first cutting tool B1. The blade edge B2c of the blade B2 is located. Accordingly, the cutting edges B1c of the first cutting tool B1 and the cutting edges B2c of the second cutting tool B2 are displaced from each other in the rotational direction by 1/2 pitch. That is, as will be described later, the two cutting tools B1 and B2 are attached with the cutting edges B1a and B2a shifted by 1/2 pitch.

Next, the inner flange 11 of the first flange pair P1 is non-rotatably mounted on the spindle 1 via flat surfaces 1d and 1d formed on the boss 1b of the spindle 1. The outer flange 12 of the first flange pair P1 is positioned in the rotational direction with respect to the inner flange 11 by the positioning pin 11d of the inner flange 11 being inserted into the positioning hole 12c. In this positioning state, the portion with the maximum thickness of the inner flange 11 and the portion with the minimum thickness of the outer flange 12 face each other, the portion with the minimum thickness of the inner flange 11 and the portion with the maximum thickness of the outer flange 12. Are opposed to each other, and the inclined mounting surface 11K of the inner flange 11 and the inclined mounting surface 12K of the outer flange 12 are opposed to each other, and the first cutting tool B1 is sandwiched between the inclined mounting surfaces 11K and 12K. For this reason, the first cutting tool B1 is attached to the spindle 1 in an inclined state with an angle θ.
A positioning pin 11d is inserted into the positioning hole B1b of the first cutting tool B1. This positioning pin 11d is inserted into the positioning hole B1b of the first cutting tool B1, and further inserted into the positioning hole 12c of the outer flange 12 as described above. The positioning pins 11d position the flanges 11 and 12 and the first cutting tool B1 in the mutual rotational direction. That is, the positioning pin 11d has a function of positioning and fixing the outer flange 12 in the rotational direction with respect to the inner flange 11 and a function of positioning the blade B1 in the rotational direction. The positioning pin 11d corresponds to the first positioning pin described in the claims, and the positioning hole 12c corresponds to the first positioning hole. Further, the positioning pin 11d and the positioning hole 12c constitute a first positioning portion T1 of the first flange pair P1.

The inner flange 13 of the second flange pair P2 is mounted on the orthogonal mounting surface 12T side of the outer flange 12 of the first flange pair P1. The positioning pin 13c of the inner flange 13 in the second flange pair P2 is inserted into the positioning hole 12c of the outer flange 12 in the first flange pair P1. Thereby, the first flange pair P1 and the second flange pair P2 are positioned and fixed in the rotational direction. Accordingly, the positioning pin 13c in this example corresponds to the second positioning pin described in the claims, and the positioning hole 12c into which the positioning pin 13c is inserted corresponds to the second positioning hole. The positioning pin 13 and the positioning hole 12c constitute a second positioning portion described in the claims. The positioning hole 12c in this example functions as a positioning hole for the first positioning portion T1, and also functions as a positioning hole for the second positioning portion, and also serves as a positioning hole for both positioning portions. In the positioning state by the second positioning portion, the inner flange 13 of the second flange pair P2 is in a state in which the portion with the maximum plate thickness matches the portion with the maximum plate thickness of the outer flange 12 in the first flange pair P1. It is installed with. Therefore, the inner flange 11 of the first flange pair P1 and the inner flange 13 of the second flange pair P2 are mounted in a state where they are shifted from each other by 180 ° in the rotational direction.
The positioning pin 13d of the inner flange 13 is inserted into the positioning hole 14c of the outer flange 14 in the second flange pair P2. Thereby, the inner flange 13 and the outer flange 14 are positioned and fixed in the rotational direction. The positioning pin 13d corresponds to the first positioning pin described in the claims, and the positioning hole 14c corresponds to the first positioning hole. Further, the positioning pin 13d and the positioning hole 12c constitute a first positioning portion T1 of the second flange pair P2. In this positioning state, the portion with the maximum plate thickness of the outer flange 14 matches the portion with the minimum plate thickness of the inner flange 13. Accordingly, the outer flange 12 of the first flange pair P1 and the outer flange 14 of the second flange pair P2 are mounted so as to be shifted from each other by 180 ° in the circumferential direction. The positioning pin 13d of the inner flange 13 is inserted into the positioning hole B2b of the second blade B2.
From the above, the first flange pair P1 and the second flange pair P2 are mounted 180 ° apart from each other in the circumferential direction. For this reason, the first cutting tool B1 and the second cutting tool B2 are mounted 180 degrees apart from each other in the rotational direction, and therefore are inclined in the opposite directions at the same inclination angle with respect to the axis of the spindle 1, that is, It is in a state of plane symmetry (as shown in FIG. 1, a square shape is seen from the side). In this specification, plane symmetry refers to the tilt direction and tilt angle with respect to the axis of the spindle 1. In this example, the blades B1 and B2 are not plane-symmetric with respect to the positions of the blade edges B1c and B2c and the positioning holes B1b and B2b.
From this, in the abutting portion of both the cutting tools B1 and B2 (the portion at the peripheral edge of both cutting tools S1 and S2 and the cutting edges B1c and B2c approaching, the portion shown in FIG. 7), as described above, the first cutting tool B1. The cutting edge B1c and the cutting edge B2c of the second cutting tool B2 are shifted from each other by 1/2 pitch in the rotational direction.
In addition, the cutting edge B1c of the first cutting tool B1 and the cutting edge B2c of the second cutting tool B2 slightly overlap in the plate thickness direction (rotation axis L direction) in the abutting portion. The inclination angle θ of both the cutting tools B1 and B2 and the position in the direction of the rotation axis L are appropriately set so that the cutting edges B1a and B2a of the both cutting tools B1 and B2 overlap in the plate thickness direction.

According to the blade attachment device 10 of the present embodiment configured as described above, the attachment tool B1a (B2a) is provided at the center, and if one positioning hole B1b (B2b) is additionally machined, the tool B1 (B2) is provided. Since it can be attached to the spindle 1 while being inclined, it is possible to use a highly versatile cutting tool which is usually commercially available, unlike the conventional one, thereby improving the versatility of the grooving machine itself. it can.
Moreover, according to the illustrated blade attachment device 10, since the two blades B1 and B2 are attached in a state inclined in opposite directions to each other, the vibration generated by the inclination is offset, and the result In particular, vibration during spindle rotation can be suppressed. In addition to this, as shown in FIGS. 6 and 8, the cutting edges B1c to B1c and B2c to B2c of the two cutting tools B1 and B2 are alternately shifted along the circumferential direction by approximately 1/2 pitch, and As shown in FIGS. 7 and 8, the cutting edges B1c and B2c are attached so as to overlap each other in the plate thickness direction, so that there is no uncut portion R at the bottom of the groove M to be processed, and the finish is finished. Can be processed cleanly. As shown in FIG. 13, if the cutting edges of the two cutting tools do not overlap as described above, an uncut portion R is generated at the bottom of the groove. In FIGS. 7 and 8, the range where the blade edges B1c and B2c overlap is indicated by the reference symbol OP.
Furthermore, according to the blade attachment device 10 of the present example, the blade can be attached in various modes other than the above-illustrated embodiment. For example, FIG. 9 shows a state where one blade tool B3 is sandwiched between the first flange pair P1 and the second flange pair P2 and attached to the spindle 1 in an orthogonal state. In this case, the blade attachment device 10 has the same configuration as described above. The blade B3 is sandwiched between the orthogonal mounting surface 12T of the outer flange 12 on the first flange pair P1 side and the orthogonal mounting surface 13T of the inner flange 13 on the second flange pair P2 side. The positioning pin 13c of the inner flange 13 is inserted into the positioning hole B3b of the blade B3, and the rotation of the blade B3 with respect to the spindle 1 is prevented. The blade B3 is exactly the same as the blades B1 and B2.
As described above, the blade attachment device 10 of this example can attach the two blades B1 and B2 to the inclined state as described above, and attach one blade B3 to the spindle 1 in an orthogonal state. In this case, it is possible to cut or cut the workpiece.

Next, FIG. 10 shows an attachment state in which one blade B4 is inclined with respect to the spindle 1 at an angle θ. The blade B4 has the same configuration as the blades B1 to B3. This attachment form corresponds to the attachment form of the blade B2 alone in the attachment form shown in FIG. In this case, the cutting tool B4 is sandwiched between the inclined mounting surface 13K of the inner flange 13 and the inclined mounting surface 14K of the outer flange 14 on the second flange pair P2 side. Further, the positioning pin 13d of the inner flange 13 is inserted into the positioning hole B4b of the blade B4 to prevent the spindle 1 from rotating. In this way, the grooving process with a constant width W4 can also be performed by attaching one blade tool B4 so as to be inclined with respect to the spindle 1.
Further, FIG. 11 shows a state where four blades B5 to B8 are mounted using the exemplified blade attachment device 10. In this case, the fifth cutting tool B5 is sandwiched between the flange portion 1a of the spindle 1 and the inner flange 11 of the first flange pair P1 and fixed in an orthogonal state, and the inner flange 11 and the outer flange 12 of the first flange pair P1 are fixed. The sixth cutting tool B6 is fixed in an inclined state. Further, the seventh cutting tool B7 is fixed between the inner flange 13 and the outer flange 14 of the second flange pair P2 so as to be inclined to the opposite side to the sixth cutting tool B6, and between the outer flange 14 and the fixing nut 2. The eighth cutting tool B8 is fixed in an orthogonal state.

The positioning pin 11c of the inner flange 11 is inserted into the positioning hole B5b of the fifth cutting tool B5, and the positioning pin 11d of the inner flange 11 of the positioning hole B6b of the sixth cutting tool B6 is inserted and prevented from rotating with respect to the spindle 1 respectively. It is attached in a state. Further, the positioning pin 13d of the inner flange 13 of the second flange pair P2 is inserted into the positioning hole B7b of the seventh cutting tool B7 to prevent the seventh cutting tool B7 from rotating with respect to the spindle 1. The eighth cutting tool S8 is sandwiched and fixed between the orthogonal mounting surface 14T of the outer flange 14 and the fixing nut 2.
Between the cutting edge B5c of the fifth cutting tool B5 and the cutting edge B6c of the sixth cutting tool B6, between the cutting edge B6b of the sixth cutting tool B6 and the cutting edge B7b of the seventh cutting tool B7, and between the cutting edge B7b of the seventh cutting tool B7 and the eighth cutting tool B8. Since there is an overlap OP between the blade edge B8b and the blade edge B8b in the same manner as described above, it is possible to perform clean grooving without generating an uncut portion R at the bottom of the processed groove M. Thus, by mounting the four blade tools B5 to B8 in the orthogonal state and the inclined state, the groove having a large width W5 can be processed quickly and cleanly.
Further, as shown in FIG. 12, in the above-described attachment form, it is possible to adopt a form in which only the blades B5 and B8 are attached to the spindle 1 in an orthogonal state without attaching the blades B6 and B7. In this case, two grooving processes with a constant interval W6 can be performed simultaneously.
The embodiment described above can be further modified. For example, the configuration in which the inclination direction of the inclined attachment surfaces 11K and 12K of the first flange pair P1 and the inclination direction of the inclination attachment surfaces 13K and 14K of the second flange pair P2 are mounted 180 ° opposite to each other is illustrated. It is good also as a structure inclined and mounted | worn in the same direction. In this case, although not shown, the two blades B1, B2 can be mounted in parallel to each other.

Next, as illustrated above, the cutting tools B1 and B2 attached symmetrically to each other have their blade edges B1c and B2c shifted in the circumferential direction by ½ pitch from each other at their abutting portions (portions shown in FIG. 7). It is positioned and attached to the state. The same applies to the cutting tool B5 and the cutting tool B6, the cutting tool B6 and the cutting tool B7, and the cutting tool B7 and the cutting tool B8.
When two cutting tools B1 and B2 having the same number of cutting edges B1c and B2c are attached to each other by being inclined at the same angle in opposite directions, the positioning holes B1b and B2b are attached to be positioned 180 ° opposite to each other. In this case, conditions for shifting the blade edges B1c and B2c by ½ pitch from each other will be described.
When the positioning pins 12d of the second flange pair P2 are shifted by 180 ° in the rotation direction with respect to the positioning pins 11d of the first flange pair P1, the two cutting tools B1 and B2 are inclined to the opposite sides. Thus, a groove with a certain width can be formed while canceling out vibrations. In addition, the cutting edges B1b and B2b of the cutting tool B1 and the cutting edge B2b of the cutting tool B2 are shifted by about 1/2 pitch in the rotation direction (not overlapping in the rotation direction) as shown in FIGS. It is possible to make OP overlap with each other in the plate thickness direction, and as a result, clean grooving with no residual R as shown in FIG. 13 can be performed.
When the two cutting tools S1, S2 are attached to the first and second flange portions P1, P2 in an inclined state as shown in FIG. 1, the cutting edges S1b to S1b of the cutting tool S1 and the cutting edges S2b to S2b of the cutting tool S2 are automatically set. In order to attach them in a state where they are all shifted by about 1/2 pitch in the rotational direction, it is necessary to appropriately set the number of cutting edges and the circumferential position of the positioning hole with respect to the cutting edges.

Therefore, the number of cutting edges B1c to B1c and B2c to B2c of the two cutting tools B1 and B2 is the same, and the number of cutting edges B1c to B1c and B2c to B2c is an odd number. The cutting tools B1 and B2 shown in FIG. 6 each have 19 cutting edges B1c to B1c and B2c to B2c. With respect to the cutting tools B1 and B2, positioning holes B1b and B2b are additionally processed at the same position. That is, both positioning holes B1b and B2b are provided in a state where the positions in the rotational direction completely coincide with each other when the respective cutting edges B1c of the cutting tool B1 are aligned with the cutting edges B2c of the cutting tool B2. When the two cutting tools B1 and B2 are attached so that the positioning holes B1b and B2b provided in this way are located on opposite sides of 180 °, each cutting edge B1b of the cutting tool B1 is ½ pitch with respect to each cutting edge B2c of the cutting tool B2. The direction of rotation is shifted one by one. That is, the cutting edge B2c of the cutting tool B2 is positioned at the center of the two adjacent cutting edges B1c and B1c of the cutting tool B1.
In this way, for the two cutting tools B1 and B2 having the same and odd number of cutting edges B1c to B1c and B2c to B2c, positioning holes B1b and B2b are provided under the same conditions, and the positioning holes B1b and B2b are mutually connected. By attaching the two cutting tools B1 and B2 on the spindle 1 in a state of being 180 ° opposite to each other, the cutting edges B1c and B2c of the two cutting tools B1 and B2 can be shifted by 1/2 pitch in the rotation direction.
For this reason, positioning holes B1b and B2b are provided under the same conditions in two highly versatile rotary blades B1 and B2 that are usually commercially available with an odd number of chips, and the axis L of both the blades B1 and B2 By appropriately setting the position in the direction, the cutting edges B1c and B2c can be overlapped OP in the plate thickness direction as shown in FIGS. 7 and 8 at the abutting portions of the two cutting tools B1 and B2. According to this, it is possible to easily mount the two rotary blades B1 and B2 in an inclined state by using the attachment device 10 having a simpler configuration than the conventional one, and thereby, quick clean grooving without an uncut portion R can be quickly performed. Can be done.
In the above embodiment, the cutting tools B1 and B2 having 19 cutting edges have been exemplified. However, the present invention is applied to a rotating cutting tool having an odd number (21, 23 ..., 17, 15, ...). Can be applied.

It is a longitudinal cross-sectional view of the blade attachment apparatus which concerns on embodiment of this invention. This figure has shown the case where two blades are attached so as to be inclined in opposite directions. It is a side view of an inner flange. It is the figure which looked at the inner flange from the direction of arrow (3) in FIG. This figure has shown the inclination attachment surface side of the inner flange. It is a side view of an outer flange. It is the figure which looked at the outer flange from the direction of arrow (5) in FIG. This figure has shown the orthogonal attachment surface side of the outer flange. It is a side view of a blade. This figure shows a state in which two cutting tools having 19 cutting edges are overlapped with each other by 180 ° with respect to the positioning holes, and as a result, the cutting edges are shifted by 1/2 pitch between both cutting tools. It is the (7) part enlarged view of FIG. 1, Comprising: It is an enlarged view of the blade edge | tip overlapped mutually. It is the figure seen from the arrow (8) direction of FIG. 7, Comprising: It is the figure which expand | deployed and showed the state where each blade edge | tip was overlapped in the plate | board thickness direction. It is a longitudinal cross-sectional view of a blade attachment apparatus. This figure shows the case where one blade is attached perpendicularly to the spindle. It is a longitudinal cross-sectional view of a blade attachment apparatus. This figure shows a case where one blade is attached to the spindle in an inclined manner. It is a longitudinal cross-sectional view of a blade attachment apparatus. This figure shows a case where four blades are attached perpendicularly to the spindle and inclined. It is a longitudinal cross-sectional view of a blade attachment apparatus. This figure shows a case where two blades are attached perpendicularly to the spindle at regular intervals. It is a longitudinal cross-sectional view of the groove | channel processed without making a blade edge | tip overlap in a plate | board thickness direction. This figure shows a state in which an uncut residue is generated at the bottom of the processed groove.

Explanation of symbols

B1 ... 1st blade, B2 ... 2nd blade B1a, B2a ... Mounting hole, B1b, B2b ... Positioning hole, B1c, B2c ... Cutting edge B3-B8 ... 3rd-8th blade B3b ... Positioning hole 1 ... Spindle, L ... Spindle axis of rotation 1a ... flange part, 1b ... boss part, 1c ... male screw part, 1d ... flat surface 2 ... fixing nut 10 ... blade attachment device P1 ... first flange pair P2 ... second flange pair 11 ... inner flange (first 1 flange pair)
11a ... Mounting hole, 11b ... Recess, 11c, 11d ... Positioning pin, 11e ... Boss part 11f ... Flat surface 11T ... Orthogonal mounting surface, 11K ... Inclined mounting surface 12 ... Outer flange (first flange pair)
12a ... Mounting hole, 12b ... Boss portion, 12c ... Positioning hole, 12d ... Flat surface 12T ... Orthogonal mounting surface, 12K ... Inclined mounting surface 13 ... Inner flange (second flange pair)
13c ... Positioning pin, 13d ... Positioning pin 13T ... Orthogonal mounting surface, 13K ... Inclined mounting surface 14 ... Outer flange (second flange pair)
14c ... Positioning hole 14K ... Inclined attachment surface, 14T ... Orthogonal attachment surface θ ... Inclination angle M of inclined attachment surfaces 11K, 12K with respect to orthogonal attachment surfaces 11T, 12T ... Groove R ... Uncut material OP ... Overlapping portions W1, W4 of the blade edge ... width W6 of groove M ... interval of incision

Claims (6)

In a processing machine provided with a spindle that is rotated by a motor, a blade attachment device for attaching a circular blade to the spindle,
An inner flange and an outer flange mounted so as not to rotate relative to the spindle;
One end face of each of the inner flange and the outer flange is an inclined mounting surface that is inclined at the same angle with respect to the rotation axis of the spindle,
A blade attachment device configured to attach the blade between the inclined attachment surfaces of both flanges and attach the blade in an inclined state with respect to the rotation axis of the spindle. The blade attachment device according to claim 1,
A cutting tool mounting apparatus comprising a first positioning portion for positioning the inner flange and the outer flange in the rotational direction so that their inclined mounting surfaces are parallel to each other. The blade attachment device according to claim 2,
The 1st positioning part is a cutter attachment apparatus made into the structure which has a function which positions a cutter in a rotation direction with respect to an inner flange and an outer flange. The blade attachment device according to any one of claims 1 to 3,
Cutting tool mounting in which the inner flange and the outer flange are paired as a pair of flanges, and two sets of the flange pairs are adjacent to each other so that the two cutting tools can be mounted in an inclined state with respect to the rotation axis of the spindle. apparatus. The blade attachment device according to claim 4,
A second positioning portion for positioning the two pairs of flanges in the rotational direction is provided, and the second positioning portions allow the inclined directions of the two blade tools in both flange pairs to be mutually relative to the plane perpendicular to the spindle. A blade attachment device configured to be positioned in a plane-symmetrical position. The blade attachment device according to claim 5,
The first positioning portion includes a first positioning pin provided on one of an inner flange and an outer flange in each flange pair and a first positioning hole provided on the other, and the first positioning pin is inserted into the first positioning hole. The inner flange and the outer flange are positioned relative to each other in the rotational direction,
The second positioning portion includes a second positioning pin provided in one flange pair and a second positioning hole provided in the other, and the flange pair rotates by inserting the second positioning pin into the second positioning hole. It is configured to be mutually positioned in the direction,
A blade attachment device configured to also serve as the first positioning pin as the second positioning pin of the second positioning portion, or to serve as the first positioning hole as the second positioning hole.

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