JP6266129B2 - Cutting device - Google Patents

Description

  The present invention relates to a cutting apparatus that performs cutting of a workpiece attached to a processing machine.

In a conventional machine tool such as a lathe, the cutting tool generates heat at the tip of the cutting edge for machining the work material, and when it becomes high temperature, there is a tendency for the tool wear to be accelerated or the shape accuracy of the work material to deteriorate due to thermal expansion. is there. In particular, when cutting difficult-to-cut materials or high-hardness materials, or when performing high-speed cutting with a cutting speed of 200 m / min or more for the purpose of improving the working efficiency, the tip of the blade tip becomes extremely hot.
Conventionally, cooling is performed by vigorously supplying coolant from a dedicated nozzle toward the tool or work material, but in long work materials, the local coolant supply does not cool the whole, so showering In some cases, the tool and the entire work material are cooled in the form of a sheet (see, for example, Patent Document 1).
In addition, there is a coolant supply port provided in a guard including prevention of chip scattering so that the coolant supply does not deviate from the cutting area and is supplied in a shower shape to cool the tool and the entire work material (for example, Patent Document 2).

Japanese Utility Model Publication No. 4-102754 (first page, FIG. 1) Japanese Utility Model Publication No. 6-74250 (first page, FIG. 1)

For cutting difficult-to-cut materials or high-hardness materials or high-efficiency high-speed cutting, use a cutting edge with excellent heat resistance, such as cemented carbide or cermet, and increase the cutting temperature by increasing the cutting speed. Processing is done by softening the cutting material. As described in Patent Document 1 or Patent Document 2, when the coolant is directly applied to the cutting edge that has reached a high temperature, these tools having low thermal conductivity cause thermal cracking and boundary wear, As a result, the surface roughness of the steel deteriorates, and the softening of the work material is hindered, leading to an increase in cutting resistance.
On the other hand, when high-speed cutting is performed without supplying coolant, shape accuracy deteriorates due to deformation due to thermal expansion of the work material.

  The present invention has been made in order to solve the above-mentioned problems, and by suppressing the shape change due to heat storage of the work material while maintaining the high temperature state of the cutting edge, the boundary due to the thermal crack of the cutting edge An object of the present invention is to provide a cutting apparatus that can suppress high-speed cutting stably without causing deterioration of the surface roughness of the work material by suppressing wear.

The cutting device according to the present invention includes:
A cutting device configured to cool the work material by coolant while cutting the work material held by the holding unit while rotating the work material by applying the cutting edge of the cutting tool, and supplying the coolant The coolant supply nozzle has an injection port on the rear side in the rotation direction of the work material with respect to the cutting edge, and the coolant flowing out from the injection port is on the front side in the feed direction of the cutting tool from the cutting edge. It arrange | positions in the position supplied.

  According to the present invention, the coolant supply nozzle has an injection port on the rear side in the rotation direction of the work material with respect to the cutting edge, and the coolant that has flowed out of the injection port is more in the feed direction of the cutting tool than the cutting edge. By disposing at the position where it is supplied to the front side, the supplied coolant will not be applied directly to the cutting edge of the cutting tool, so the cutting edge of the cutting tool is maintained at a high temperature while cooling the work material. High-speed cutting can be realized stably. Therefore, it is possible to improve the machining accuracy without deteriorating the surface roughness of the work material.

It is a top view which shows notionally the principal part of the cutting apparatus in Embodiment 1 of this invention. It is a block diagram in the cross section which follows the II-II line | wire of FIG. It is a top view which shows notionally the principal part of the cutting apparatus in Embodiment 2 of this invention. It is a block diagram in the cross section which follows the IV-IV line | wire of FIG. It is a top view which shows notionally the principal part of the cutting apparatus in Embodiment 3 of this invention. It is a side view of the principal part of the cutting apparatus shown by FIG. It is a top view which shows notionally the principal part of the cutting apparatus in Embodiment 4 of this invention. It is a block diagram in the cross section which follows the VIII-VIII line of FIG. It is a top view which shows notionally the principal part of the cutting apparatus in Embodiment 5 of this invention. It is a block diagram in the cross section which follows the XX line of FIG. It is a principal part side view which shows notionally the modification of the cutting apparatus in Embodiment 5 of this invention. It is a principal part side view which shows notionally the other modification of the cutting apparatus in Embodiment 5 of this invention. It is a top view which shows notionally the principal part of the cutting apparatus in Embodiment 6 of this invention. It is a block diagram in the cross section which follows the XIV-XIV line | wire of FIG.

Embodiment 1 FIG.
FIG. 1 is a top view conceptually showing a main part of a cutting apparatus according to Embodiment 1 of the present invention, and FIG. 2 is a configuration diagram in a cross section taken along line II-II in FIG. In the figure, a cutting device 1 is provided with gripping portions 10a for gripping one end of a workpiece 2 as a workpiece at three locations in the circumferential direction, and a chuck as a holding portion that is rotated by a driving motor (not shown). 10 and a chuck 10 that is provided at a position opposite to the chuck 10 and holds the rotation center of the other end of the work material 2 and a cutting tool 12 that performs cutting are mounted and controlled to move in a desired direction. And a coolant supply for injecting coolant 14 </ b> C supplied from a tank (not shown) containing liquid coolant for cooling the work material 2 onto the work material 2. Nozzle 14.

The injection port of the coolant supply nozzle 14 is on the rear side in the rotation direction of the work material 2 with respect to the cutting edge or cutting edge of the cutting tool 12 (the rear side of the white arrow in FIG. 2), and the coolant supply nozzle 14. The coolant 14C that has flowed out of the workpiece 2 is supplied to the front side in the cutting tool feed direction with respect to the cutting edge of the work material 2, and is disposed at a position where the coolant 14C is not directly applied to the cutting edge. Here, the front side in the cutting tool feed direction from the cutting edge of the work material 2 refers to the region of the work material 2 that is closer to the chuck 10 than the cutting position of the cutting tool 12 in the work material 2 shown in FIG. Say. That is, the coolant 14 </ b> C is injected to an unprocessed portion where the work material 2 will be cut by the cutting tool 12 in the future. Further, the coolant supply nozzle is arranged so that the coolant 14 </ b> C flowing out from the coolant supply nozzle 14 is not directly applied to the cutting tool 12.
Further, the range of the angle θ1 (see FIG. 1) between the central axis of the work material 2 and the coolant supply nozzle 14 is such that the coolant supply nozzle 14 and the gripping portion 10a are prevented from interfering with each other, and the coolant 14C is not directly applied to the blade edge. Therefore, it is preferably 0 to 90 degrees.
The chuck 10 rotates while the work material 2 is held by the chuck 10 and the core push stand 11. In this example, the chuck 10 is provided on a rotating shaft of a driving motor (not shown). Other configurations such as a control device for the drive motor are the same as those of the conventional cutting apparatus, and thus description thereof is omitted.

  Next, the operation will be described. The cutting tool 12 is fixed to the tool post 13, and the cutting tool 12 is given cutting and feeding with respect to the work material 2 by moving the tool post 13, and the rotating work material 2 is processed. Done. The coolant supply nozzle 14 for cooling the work material 2 is moved by the tool post 13 to move the coolant supply nozzle 14 to an unprocessed portion of the work material 2, and the coolant 14C causes the unprocessed portion of the work material 2 to move. Can be cooled.

Then, when the cutting tool 12 cuts into the work material 2 while the chuck 10 and the work material 2 are rotated in the direction of the white arrow in FIG. 2, the work material is, for example, 2000 rpm because of high speed cutting. The coolant 14 </ b> C supplied from the coolant supply nozzle 14 flows down to the upper surface portion of the work material 2 and cools the work material 2 in FIG. 2. When the work material 2 rotates about 180 ° in the direction of the arrow, most of the work material 2 is scattered by centrifugal force from the outer peripheral surface of the work material 2 and falls even by gravity. The coolant 14 </ b> C reaching the position 12 is a minute amount that wets the surface of the work material 2. Therefore, cutting is performed without directly cooling the cutting edge of the cutting tool 12 and lowering the temperature of the cutting edge.
Further, since the cutting edge of the cutting tool 12 is arranged on the front side in the rotation direction of the work material (the front side of the white arrow), in other words, the injection port of the coolant supply nozzle is behind the rotation direction of the work material. Since the coolant 14C which is disposed on the side (the rear side of the white arrow) and splattered coolant does not directly collide with the blade edge to cool the blade edge, the scattered coolant hardly affects the blade temperature. That is, in FIG. 2, the angle formed between the injection direction vector of the coolant 14C and the rotation direction vector of the work material at the intersection of the center axis of the coolant supply nozzle 14 and the work material 2 is determined based on the latter vector. The injection port of the coolant supply nozzle is arranged so as to have an angle in the range of 0 to 90 degrees in the rotation direction of the work material.
That is, the angle θ2 between the tangent line (outside diameter of the work material) at the intersection of the center axis of the coolant supply nozzle 14 (that is, the injection direction of the coolant 14C) and the work material 2 and the center axis of the coolant supply nozzle 14. The range of the angle when the tangent is set to 0 degrees as a reference (see FIG. 2) is preferably 0 degrees to 90 degrees. More preferably, in order to prevent the coolant 14C from protruding from the work material 2 for efficient cooling, for example, when the outer diameter of the work material 2 is 60 mm and the inner diameter of the coolant supply nozzle 14 is 5 mm, the angle θ2 The range of 5 to 90 degrees.
Then, with the rotation center of the work material as the center position, an angle θ3 on the rear side in the rotation direction between the intersection of the center axis of the coolant supply nozzle 14 and the work material 2 and the cutting position (based on the mounting angle position of the cutting edge) The angle in the case of 0 degree (see FIG. 2) is preferably 0 to 180 degrees in order to reduce the coolant that wraps around the cutting edge. More preferably, in order to prevent the coolant 14C from directly hitting the cutting edge, the angular position on the work material to which the coolant is supplied by the coolant supply nozzle is centered on the rotation center of the work material and the cutting edge A rotation angle position determined from the rotation speed of the work material is the rear side in the rotation direction of the work material, starting from the attachment position. This is because the centrifugal force generated in the coolant is determined by the rotational speed of the work material, in other words, the peripheral speed. From the above, as an example of a more preferable range of θ3, for example, when the outer diameter of the work material 2 is 60 mm, the rotation speed is 2000 rpm, the inner diameter of the coolant supply nozzle 14 is 5 mm, and the angle θ2 is 45 degrees, it is 3 degrees to 180 degrees. Degrees.

A specific embodiment will be described. When machining is performed by supplying coolant 14C directly to a general cutting edge simulating a conventional apparatus and cooling, the work material is 6.3S (surface roughness Rz is 6.3 μm) at a cutting distance of 2.6 km. For example, when cutting is performed using the cutting apparatus according to the first embodiment, the carbide tool P10 type (JIS classification symbol) is used as the cutting tool 12, for example. When cutting S35C (JIS classification symbol), which is structural carbon steel, as the work material 2 at a speed of about 400 m / min, the surface roughness Rz of the work material even at a cutting distance of 7.3 km Was 4.6 μm, and the boundary wear was clearly suppressed, and a machined product with good surface roughness could be obtained.
In the first embodiment, since cutting is performed with the cutting edge maintained at a high temperature, chips are also discharged in a heated state, so that the coolant 14C is water-soluble with no risk of ignition. It is preferable to use the type.

As described above, according to the first embodiment, the injection port of the coolant supply nozzle 14 is located behind the cutting edge of the cutting tool 12 in the rotation direction of the workpiece 2 and is fed from the cutting edge to the cutting tool. The coolant 14C sprayed from the coolant supply nozzle 14 is directly supplied to the work material 2 and is not directly applied to the cutting edge of the cutting tool 12 by being arranged at the front portion in the direction. The coolant 14 </ b> C supplied to the outer peripheral surface of the work material 2 is arranged by gravity and centrifugal force from the position supplied by the rotation of the work material 2 to the position of the cutting tool 12. It will not drop or fly and will not directly hit the cutting edge of the cutting tool 12. Therefore, the cutting edge can be maintained at a high temperature, and the work material 2 is cooled by the coolant 14C and the work material temperature is stabilized, so that high-speed cutting can be performed stably.
As a result, the machining accuracy can be improved and the tool is not rapidly cooled, so that boundary wear does not occur and the surface roughness of the work material does not deteriorate. Further, productivity can be improved and the processing cost can be reduced.

Embodiment 2. FIG.
FIG. 3 is a top view conceptually showing a main part of the cutting apparatus according to Embodiment 2 of the present invention, and FIG. 4 is a configuration diagram in a cross section taken along line IV-IV in FIG. In the figure, in the lower part of the work material 2, the coolant 14 </ b> C adhering to the work material 2 is recovered at a position corresponding to the injection port of the coolant supply nozzle 14 in the rotation axis direction of the work material 2. The coolant suction pipe 15 is installed. The coolant suction tube 15 is formed in a nozzle shape or funnel shape with its upper end widened, and has a function of sucking the coolant 14C over a wide range. Further, by attaching the air blow nozzle 18 to the rear of the coolant suction pipe 15 in the rotation direction, the coolant 14C can be blocked by the air curtain. Since other configurations are the same as those of the first embodiment, description thereof is omitted.

In the second embodiment configured as described above, the coolant suction pipe 15 is disposed below the work material 2 (a position below the work material in the direction of gravity; the same applies hereinafter), whereby the cutting tool 12 is provided. It is possible to reduce the coolant 14 </ b> C that wraps around as much as possible and to perform cutting while maintaining the high temperature of the cutting tool 12 as in the first embodiment. Therefore, by not supplying coolant directly to the tool cutting edge, the work material temperature is stabilized and machining accuracy is improved, and since the tool is not rapidly cooled, boundary wear does not occur and deterioration of the surface roughness of the work material does not occur. The effect is obtained. Further, by attaching the air blow nozzle 18, it is possible to further reduce the coolant 14 </ b> C that goes around the cutting tool 12. In this example, both the coolant suction pipe 15 and the air blow nozzle 18 are installed, but the effect can be expected with only one of them.
Although the coolant suction pipe 15 is installed below the work material 2, it is possible to collect coolant and chips at the same time by installing it near the cutting area of the cutting tool 12. In this case, it is necessary to incorporate a mechanism for separating coolant and chips, or dividing or cutting long chips. Further, when the air blow nozzle 18 is used in combination, the cutting of the cutting tool 12 by air is prevented by attaching the air blow nozzle 18 to the rear in the rotational direction of the coolant suction pipe, and recovery can be performed without scattering chips. Moreover, since Embodiment 2 can also perform cutting with the cutting edge maintained at a high temperature, as in Embodiment 1, the chips are also discharged with heat, and as the coolant 14C It is desirable to use a water-soluble type that has no risk of ignition.

Embodiment 3 FIG.
FIG. 5 is a top view conceptually showing the main part of the cutting apparatus according to Embodiment 3 of the present invention, and FIG. 6 is a side view of the main part of the cutting apparatus shown in FIG. In the drawing, a cutting tool 12A for performing cylindrical inner diameter processing is fixed to a tool post 13, and the cutting tool 12A is given cutting and feeding to the work material 2 by rotating the tool post 13, and rotates. The inner diameter portion 2a of the workpiece 2 is processed. The tool rest 13 is also provided with a coolant supply nozzle 14 for cooling the work material 2, and the coolant supply nozzle 14 is moved to the outer peripheral surface of the work material 2 by moving the tool rest 13. The workpiece 2 can be cooled from the outer surface side by 14C.

  In the third embodiment configured as described above, the coolant 14C is supplied to the outer peripheral surface of the work material 2 and does not directly contact the cutting edge of the cutting tool 12A, so that the high temperature of the cutting tool 12A is maintained. Processing can be performed. Therefore, the temperature of the work material is stabilized and the machining accuracy is improved, and since the tool is not rapidly cooled, boundary wear does not occur and the surface roughness of the work material does not deteriorate. Further, the coolant 14C, the cutting tool 12A, and chips (not shown) are not easily in contact with each other. However, since the chips are hot, it is desirable to use a water-soluble type with no risk of ignition for the coolant 14C. In addition, the coolant suction pipe 15 shown in the second embodiment can be installed to collect the coolant 14C.

Embodiment 4 FIG.
FIG. 7 is a top view conceptually showing the main part of the cutting apparatus according to Embodiment 4 of the present invention, and FIG. 8 is a configuration diagram in a section taken along line VIII-VIII in FIG. In the drawing, a holder 12B with a heat insulation type coolant supply hole for processing is fixed to the tool post 13, and an insert 121 which is a cutting tool of a cutting tool is attached to the holder 12B with a heat insulation type coolant supply hole. Yes. A coolant injection port 14 a is opened on the flank side of the insert 121.
The holder 12B with adiabatic coolant supply hole is provided with a pipe line penetrating the inside, and the pipe line communicates with the coolant injection port 14a in a thermally insulated state so as not to cool the blade edge through the holder. The tool post 13 is supplied with a coolant 14C from a machine tool main body (not shown), and the supplied coolant 14C is fed from the coolant injection port 14a via the above-mentioned pipeline of the holder 12B with a heat insulating coolant supply hole. It is configured to be supplied to the cutting material 2.
Further, in the tool post 13 and the holder 12B with the adiabatic coolant supply hole, the coolant 14C (the center of the flow) injected from the coolant injection port 14a is on the rear side in the rotation direction from the cutting edge of the work material 2 and is a cutting tool. It is arranged to be on the front side in the feed direction. Since other configurations are the same as those of the first embodiment, description thereof is omitted.

In the fourth embodiment configured as described above, by moving the tool post 13, the holder 12 </ b> B with the adiabatic coolant supply hole and the insert 121 are given cutting and feeding to the work material 2 and rotate. The workpiece 2 is processed. The coolant injection port 14a is opened on the flank side of the insert 121, and the coolant injection port 14a faces in a direction not hitting the holder 12B with the heat insulating coolant supply hole, so that the injected coolant 14C directly contacts the tool. Since the work material 2 can be cooled without cooling, it is possible to perform processing while maintaining the tip of the insert 121 at a high temperature.
Therefore, the work material temperature is stabilized and the machining accuracy is improved, and since the tool is not rapidly cooled, boundary wear does not occur and the surface roughness of the work material does not deteriorate. In addition, by providing the coolant injection port 14a on the tool clearance surface side, the distance to which the coolant is shaken is extended by the rotation of the work material. Therefore, the tool can be prevented from being rapidly cooled by splashing of the coolant to prevent boundary wear. Deterioration of surface roughness is less likely to occur.

In addition, since Embodiment 4 can also perform cutting with the cutting edge maintained at a high temperature, as in Embodiment 1, chips are also discharged with heat, and the coolant 14C It is desirable to use a water-soluble type that has no risk of ignition.
Further, the coolant supply nozzle 14 shown in the first embodiment is installed, and the coolant 14C is simultaneously supplied from the coolant supply nozzle 14 for processing, or the coolant suction pipe 15 or the air blow nozzle 18 shown in the second embodiment. It is also possible to install.

Embodiment 5. FIG.
FIG. 9 is a top view conceptually showing the main part of the cutting apparatus according to Embodiment 5 of the present invention, and FIG. It is. In the drawing, a heating fluid supply for supplying a heating fluid 16a such as heated air or superheated steam to the cutting edge portion as external heating means 16 for raising the temperature of the cutting edge portion of the cutting tool 12 before processing is provided on the tool post 13. A nozzle 16A is provided, and a heating fluid generator (not shown) for generating the heating fluid 16a and a temperature control device (not shown) for the heating fluid 16a are provided. The temperature of the heating fluid 16a is preferably up to about 200 ° C. because adding a temperature exceeding 200 ° C. to the work material 2 may cause oxidation.
Although the cutting edge portion can be heated during processing, depending on the cutting conditions, the cutting area of the cutting tool 12 may be 800 ° C. or higher, and heating at 200 ° C. means cooling the cutting edge. Heating immediately before processing is appropriate. Since other configurations are the same as those of the first embodiment, description thereof is omitted.

  In the fifth embodiment configured as described above, the heating fluid 16a is jetted from the heating fluid supply nozzle 16A to the cutting edge of the cutting tool 12 before cutting, and the cutting edge before processing is heated to a predetermined temperature in advance. By doing so, it is possible to mitigate the rapid temperature rise of the cutting tool 12 at the start of cutting. For this reason, it is possible to extend the life of the cutting tool 12, and it is possible to obtain a further effect that high-precision cutting can be performed immediately after the start of cutting.

FIG. 11 is a side view of an essential part conceptually showing a modification of the cutting apparatus according to Embodiment 5 of the present invention. In this modification, a laser heater 16B is used as the external heating means 16. In the figure, a laser heater 16B installed at a position facing the cutting edge portion of the cutting tool 12 is provided in the cutting apparatus main body.
In the modified example configured as described above, the cutting is started by moving the cutting tool 12 to the focal point of the laser beam L irradiated from the laser heater 16B and raising the temperature of the tool edge before processing. It is possible to mitigate sudden temperature rise. In this example, it is assumed that the temperature increases immediately after the tool post is replaced at the retracted position for finishing cutting. However, the temperature can be increased after the tool is retracted at intervals during cutting. It is.

FIG. 12 is a side view of an essential part conceptually showing another modification of the cutting apparatus according to Embodiment 5 of the present invention. In this modification, an induction heater 16C using electromagnetic induction is used as the external heating means 16. In the figure, an induction heater 16C for raising the temperature of the cutting edge portion of the cutting tool 12 before processing is provided in the cutting apparatus main body.
In another modified example configured as described above, the cutting tool 12 is moved to the vicinity of the induction heater 16C installed in the cutting apparatus main body, and the tool blade tip is heated to perform the machining. It is possible to mitigate a rapid temperature rise at the start of cutting. In this example as well, it is assumed that the temperature rises immediately after the tool post is changed at the retracted position for finishing cutting, but it is also possible to raise the temperature after the tool is retracted at the interval during cutting. is there.

Since the fifth embodiment is provided with a heating means, it is necessary to use a water-insoluble coolant whose flash point is lower than the heating temperature, but the processing is similar to the first embodiment. Since cutting is performed with the blade maintained at a high temperature, chips are also discharged in a heated state, and it is desirable to use a water-soluble type with no risk of ignition for the coolant 14C.
Further, the coolant suction pipe 15 or the air blow nozzle 18 shown in the second embodiment is installed in the configuration of the fifth embodiment, or processing is performed using the holder 12B with a heat insulating coolant supply hole shown in the fourth embodiment. It is also possible. Furthermore, the tool edge can be heated using the tool temperature raising method of the fifth embodiment for the in-cylinder cutting shown in the third embodiment.

As described above, according to the fifth embodiment, the high-temperature fluid is supplied by the heating fluid supply nozzle 16A, or the external heating means 16 such as the laser heater 16B or the induction heater 16C is provided. By raising the temperature to a temperature of 1, it is possible to reduce the temperature gap from the time of cutting and to prevent deterioration of the surface roughness of the work material due to thermal cracking of the tool edge. In addition, it is possible to mitigate the rapid temperature rise of the cutting tool 12 at the start of cutting. For this reason, it is possible to extend the life of the cutting tool 12, and it is possible to obtain a further effect that high-precision cutting can be performed immediately after the start of cutting.
In the above description, the external heating means 16 has been described on the premise that any one of the above-described three types of external heating means is used. It may be used.

Embodiment 6 FIG.
FIG. 13 is a top view conceptually showing the main part of the cutting apparatus according to Embodiment 6 of the present invention, and FIG. 14 is a configuration diagram in a section taken along line XIV-XIV in FIG. In the figure, the tool post 13 is provided with a liquid foam heat insulating material injection device as a heat retaining device 17 for retaining the temperature of the cutting tool 12 being processed. This liquid foam heat insulating material injection device has a liquid foam heat insulating material supply nozzle 17A, and is configured to be able to supply the liquid foam heat insulating material 17a to the cutting edge of the cutting tool 12 during the cutting process. The liquid foam heat insulating material 17a is generated by bubbling or the like with a foam generation device (not shown), and is supplied to the liquid foam heat insulating material supply nozzle 17A via a foam feed pipe by a pump according to the method of heat insulation. Sent continuously or intermittently. Other configurations are the same as those of the first embodiment.

As the liquid foam heat insulating material 17a, for example, by using a coolant stock solution diluted with water, the surfactant used in the coolant stock solution can be used by bubbling. In this case, the coolant undiluted solution before being diluted with water will be supplied, but the amount used is small because of the supply as foam, and there is no problem with respect to concentration fluctuations even if mixed with the coolant that cools the work material 2. In order to maintain the processing accuracy, it is desirable to periodically measure the concentration. However, since foam may remain, it is more desirable to mix an antifoaming agent with the coolant.
In addition, since foam has poor stability at high temperature, it is desirable to supply the heating medium and foam using separate nozzles in order to maintain the tool temperature.

  In the sixth embodiment configured as described above, a part of the coolant 14C for cooling the work material 2 is obtained by supplying the liquid foam heat insulating material 17a to the cutting edge of the cutting tool 12 during the cutting process. The cutting tool 12 is prevented from being rapidly cooled by being scattered and applied to the cutting edge of the cutting tool 12, and by preventing thermal insulation during processing and direct cooling of the coolant, boundary wear due to thermal cracks in the tool cutting edge is generated. It is possible to protect the tool from boundary wear and to prevent the deterioration of the surface roughness of the work material.

  It is also possible to perform processing by installing the coolant suction pipe 15 or the air blow nozzle 18 shown in the second embodiment, or using the holder 12B with a heat insulating coolant supply hole shown in the fourth embodiment. Furthermore, the temperature of the tool edge can be maintained by installing the liquid foam heat insulating material supply nozzle of the sixth embodiment in the in-cylinder cutting shown in the third embodiment.

  The external heating means 16 shown in the fifth embodiment or the heat retaining device 17 shown in the sixth embodiment constitutes a temperature holding device that holds the temperature of the cutting tool 12 in a desired range. In other words, the heating means 16 can actively increase the temperature of the cutting tool 12, so that the temperature of the cutting tool 12 can be raised in advance before the cutting process, and the tool 14 is affected by, for example, a part of the coolant 14C falling on the cutting edge during the cutting process. When the temperature is lower than the target value, the temperature can be maintained by raising the tool temperature. On the other hand, the heat retaining device 17 passively retains the temperature of the cutting tool 12 heated during processing.

  It should be noted that within the scope of the present invention, a part or all of each embodiment can be freely combined, or each embodiment can be appropriately modified or omitted.

  DESCRIPTION OF SYMBOLS 1 Cutting device, 2 Work material, 2a Inner diameter part, 10 Chuck, 10a Gripping part, 11 Core push stand, 12, 12A Cutting tool, 12B Holder with heat insulation type coolant supply hole, 121 Insert, 13 Tool post, 14 Coolant Supply nozzle, 14a Coolant injection port, 14C coolant, 15 Coolant suction pipe, 16 External heating means, 16A Heating fluid supply nozzle, 16a Heating fluid, 16B Laser heater, 16C Induction heater, 17 Heat retention device, 17A Liquid foam insulation Supply nozzle, 17a Liquid foam insulation, 18 Air blow nozzle, L Laser beam

Claims (10)

  A cutting device configured to cool the work material by coolant while cutting the work material held by the holding unit while rotating the work material by applying the cutting edge of the cutting tool, and supplying the coolant The coolant supply nozzle has an injection port on the rear side in the rotation direction of the work material with respect to the cutting edge, and the coolant flowing out from the injection port is on the front side in the feed direction of the cutting tool from the cutting edge. A cutting apparatus characterized by being arranged at a position to be supplied.   The angular position on the work material to which coolant is supplied by the coolant supply nozzle is at the rear side in the rotation direction of the work material with the rotation center of the work material as the center position and the attachment position of the cutting edge as the starting point. The cutting device according to claim 1, wherein the cutting angle position is determined from the rotation speed of the work material.   The cutting apparatus according to claim 1 or 2, wherein the injection port of the coolant supply nozzle is provided on the flank side of the cutting tool in a state of being thermally insulated from the cutting tool.   2. A coolant suction pipe or an air blow nozzle that prevents the coolant that has flowed out of the coolant supply nozzle and used to cool the work material from being provided under the work material. 4. The cutting apparatus according to any one of items 3.   The cutting device according to any one of claims 1 to 4, further comprising a temperature holding device that holds a temperature of the cutting tool.   6. The cutting apparatus according to claim 5, wherein the temperature holding device uses a heating means for heating the cutting tool from the outside. The heating means is for the cutting tool.
A heated fluid ejecting apparatus for ejecting heated fluid;
A laser heating device for heating by irradiating a laser beam;
Or induction heating device by electromagnetic induction,
The cutting apparatus according to claim 6, wherein:   The cutting apparatus according to claim 5, wherein the temperature holding device includes a heat holding device that suppresses a decrease in temperature of the cutting tool that has been raised by cutting.   9. The cutting apparatus according to claim 8, wherein the heat retaining device uses a liquid foam heat insulating material injection device that injects a liquid foam heat insulating material composed of a large number of bubbles onto the cutting tool.   The liquid foam heat insulating material injection device includes a foam generating device for foaming a coolant stock solution diluted with water, and a foam supply pipe for supplying the liquid foam heat insulating material generated by the foam generating device to the cutting tool. The cutting apparatus according to claim 9.

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