JP4189522B2 - Laser processing machine - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a processing machine, and more particularly to a processing machine that reflects radiant heat from the outside and hardly raises the temperature due to the radiant heat.
[0002]
[Prior art]
For example, there is a laser processing machine that processes a workpiece with laser light. The laser processing machine outputs laser light from a processing head, irradiates the laser beam on a processing portion of the workpiece, and raises the processing portion to a processing temperature to perform processing.
[0003]
[Problems to be solved by the invention]
When the workpiece is irradiated with the laser beam in this way, the machining location of the workpiece may suddenly rise to the machining temperature. And a big temperature gradient arises inside a workpiece | work, a big stress arises inside a workpiece | work, As a result, a crack and a crack may generate | occur | produce in a workpiece | work. In order to avoid such a situation, for example, the work is placed in a heating furnace, and before the laser beam is irradiated by the laser processing machine, the work is heated (preheated) to a temperature lower than the processing temperature, and then the laser beam is irradiated. It is conceivable to apply the processing by. An opening is formed in the heating furnace, and the workpiece is irradiated with laser light from the laser processing machine through the opening.
[0004]
However, the inside of the heating furnace is hot, and if there is an opening, radiant heat leaks from there. Therefore, when a laser processing machine is installed in the vicinity of the heating furnace, the laser processing machine receives radiant heat radiated from the opening of the heating furnace. If it does so, the temperature of a laser processing machine will rise. When this temperature rise is significant, various adverse effects occur in the laser processing machine. For example, the drive system of the laser processing machine expands due to the temperature rise, and the drive accuracy decreases. In addition, the lubricant in the drive part may deteriorate or the life of the parts may be shortened. In particular, when the temperature of the optical system inside the laser processing machine rises, the processing accuracy is adversely affected. That is, when the mirror or the lens expands due to a temperature rise, the optical axis is shifted, or the cross-sectional shape of the laser light output from the processing head is deformed.
[0005]
Furthermore, if the radiant heat leaking from the heating furnace can be used more actively in the processing of workpieces, the energy consumed by the laser processing machine and the heating furnace can be reduced and the configuration of the laser processing machine can be simplified. It should be possible.
[0008]
[Means for Solving the Problems]
In order to solve the above problems, a laser processing machine according to the present invention is a laser processing machine installed in the vicinity of a heating furnace having an opening, and the laser processing machine outputs a laser beam from its tip. The processing head irradiates the work in the heating furnace with laser light through the opening, and the processing head is irradiated with radiant heat radiated from the opening of the heating furnace. Has an optical system and a housing that covers the optical system, and a portion of the surface of the housing that is irradiated with the radiant heat from the opening is mirror-finished (Claim 1). According to such a configuration,The radiant heat from the furnace opening is effectively reflected, and the temperature rise of the processing machine due to the radiant heat can be minimized.
[0009]
In order to solve the above problems, another laser processing machine of the present invention is a laser processing machine installed in the vicinity of a heating furnace having an opening, and the laser processing machine transmits laser light at a tip thereof. The processing head irradiates the workpiece in the heating furnace with laser light through the opening, and the processing head circulates around the axis of the processing head. A reflecting member is provided, and radiant heat radiated from the opening of the heating furnace is reflected toward the opening by the reflecting member. According to such a configuration, the radiant heat from the opening of the furnace is effectively reflected, and the temperature rise of the processing machine due to the radiant heat can be minimized.
[0011]
In the laser processing machine, the processing head includes an optical system and a housing that covers the optical system, and protrudes toward the opening from the surface of the housing facing the opening of the reflecting member. The finished part may be mirror-finished (Claim 3).This is particularly effective for preventing the temperature rise of the machining head.
[0012]
In the laser processing machine, a surface of the reflecting member facing the opening may be finished in a mirror shape. Further, the surface of the reflecting member facing the opening may be concave.If it does in this way, radiant heat can be returned to a radiant heat source more efficiently by a reflective member.
[0017]
In order to solve the above problems, another laser processing machine of the present invention is a laser processing machine installed in the vicinity of a heating furnace having an opening, and the laser processing machine transmits laser light at a tip thereof. The processing head irradiates the workpiece in the heating furnace with laser light through the opening, and the processing head processes the workpiece while moving relative to the workpiece. The processing head is provided with a reflecting member so as to circulate around the axis of the processing head, and the surface of the reflecting member facing the opening is finished to be a mirror surface. Radiant heat radiated from the opening is reflected toward the opening by the surface of the reflecting member facing the opening, and the surface of the reflecting member facing the opening transmits the reflected radiant heat through the opening. Concentrate at a specific location in the furnace A shape as possible, the predetermined position from the axis of the machining head, a position at a distance along the direction of movement relative to said workpiece in said machining head (claim 6). According to such a configuration,It is possible to arrange the machining location by the machining head and the predetermined location at a distance along the machining direction on the workpiece. If it does in this way, before or after processing by a processing head, the processing part can be heated with a reflective member, and it can be made to preheat or cool slowly.
[0021]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment of the present invention will be described with reference to the drawings.
[0022]
FIG. 1 is a three-plane view showing a processing machine (laser processing machine) 10 according to an embodiment of the present invention, wherein (a) is a rear view, (b) is a side view, and (c) is a plan view. The laser processing machine 10 is installed in the vicinity of the heating furnace 30, and in the drawing, the heating furnace 30 is also shown together with the laser processing machine 10. The laser processing machine 10 includes two leg portions 11, a rail portion 12, spanned on the leg portion 11, an arm portion 13, a turning portion 14, and a machining head 15. The leg 11 is fixed to the floor surface. The arm portion 13 can move with respect to the rail portion 12 in the direction of arrow X and the direction of arrow Y in the figure. Further, the turning portion 14 can turn in the direction of arrow A in the figure with respect to the arm portion 13, and the machining head 15 can turn in the direction of arrow B in the drawing with respect to the turning portion 14. It has become. Therefore, the machining head 15 can be set at an arbitrary angle with respect to the arm portion 13 within a predetermined range. The imaginary line in the figure shows a state in which the machining head 15 has moved from the position of the solid line to another position.
[0023]
The laser light is introduced from the laser light inlet 16, passes through the inside of the bellows part 17, and is reflected by the mirrors M1 and M2 in the arm 13, the mirror M3 in the swivel part 14, and the mirror M4 in the processing head 15. Then, the light passes through the lens R in the processing head 15 and is output from the tip of the processing head 15.
[0024]
Each of the rail part 12, the arm part 13, the turning part 14, and the machining head 15 has a structure in which internal mechanisms such as a drive system and an optical system are covered with a housing. The surface of the housing of the processing head 15, the surface of the housing of the turning portion 14, and the surface of the housing of the arm portion 13 are finished in a mirror shape. To finish the mirror surface, for example, the surface of the housing may be metal-plated, a mirror-like film may be formed by vapor deposition on the surface of the housing, or mechanical polishing such as buffing may be applied to the housing surface. You may give it. Among them, the treatment by plating, particularly the treatment by chrome plating is suitable for mirror finish. The operation of the mirror-finished housing will be described later. The movement of the arm unit 13, the turning of the turning unit 14, and the turning of the machining head 15 are controlled by a control unit (not shown). The workpiece W in the heating furnace 30 is laser processed by the laser processing machine 10 configured as described above.
[0025]
FIG. 2 is a perspective view of a part of the laser processing machine 10 and the heating furnace 30. As described above, the opening 31 is formed in the heating furnace 30. This opening 31 is for guiding the laser beam of the laser processing machine 10 into the heating furnace 30. Although not shown in the drawing, a conveying device is laid in the heating furnace 30. A workpiece carry-in port 32 is formed at the end of the heating furnace 30, and the work W is carried into the heating furnace 30 from the work carry-in port 32 in a state of being fixed on the mounting table S and placed on the transfer device. . The workpiece W is conveyed in the direction of the arrow C in the drawing by the conveying device. The laser processing machine 10 performs laser processing by irradiating the workpiece W, which has been transported to the front of the laser processing machine 10 by the transport device, with laser light from the processing head 15 through the opening 31. In this case, the processing with laser light (laser processing) may be, for example, fusion or deformation processing that deforms the workpiece by heating. The workpiece W is transported through the heating furnace 30 from the workpiece carry-in port 32 to the front of the laser processing machine 10. Therefore, when the workpiece W comes to the front of the laser processing machine 10, the processing portion of the workpiece W has not reached the processing temperature, but has risen to some extent. That is, preheating is performed. Therefore, even if the main processing with the laser beam is performed, a large temperature gradient does not occur around the processing portion of the workpiece W. Therefore, cracks and cracks are less likely to occur inside the workpiece W. In addition, the workpiece W that has been subjected to the main processing by the laser beam is conveyed inside the heating furnace 30. Therefore, the machining part of the workpiece W is not rapidly cooled, and the temperature of the workpiece W is uniformly and gradually decreased. That is, the workpiece W is gradually cooled. Therefore, in the cooling process of the workpiece W, a large temperature gradient does not occur around the machining location, and cracks and cracks are not easily generated inside the workpiece W. The opening 31 is provided with a lid 33. The opening 31 is closed by a lid 33 when laser processing is not performed.
[0026]
FIG. 3 is a view showing a side view of the processing head 15 of the laser processing machine 10 and its peripheral portion together with a cross-sectional view of the heating furnace 30. An arrow D in the figure indicates the traveling direction of the laser beam. The other arrows in the figure indicate the traveling direction of radiant heat. The inside of the heating furnace 30 is hot, and radiant heat leaks from the opening 31. This radiant heat radiated from the opening 31 is irradiated particularly strongly to the portion closest to the opening 31 of the laser processing machine 10, that is, the processing head 15. However, as described above, the surface of the housing of the processing head 15 is mirror-finished, and thus reflects radiant heat. Therefore, the temperature of the internal mechanism of the machining head 15 is prevented from being significantly increased due to radiant heat. More specifically, an optical system including a mirror M4 and a lens R is provided inside the processing head 15. However, since the surface of the housing of the processing head 15 reflects radiant heat, the expansion of the mirror M4 and the lens R is performed. Therefore, deviation of the optical axis of the laser beam and deformation of the cross-sectional shape of the laser beam are prevented.
[0027]
Similarly, since the surface of the housing of the swivel unit 14 and the surface of the housing of the arm unit 13 are also mirror-finished, the optical system such as the mirrors M1, M2, and M3 provided inside the swivel unit 14 and the arm unit 13 However, the temperature rise is prevented.
[0028]
In addition, the drive system of the swivel unit 14 and the arm unit 13 is not easily expanded, so that the drive accuracy is maintained. Further, the drive system lubricant is also prevented from deteriorating due to a temperature rise. Furthermore, even if there are parts formed of materials (for example, resin or rubber) whose life is shortened by the temperature rise inside the machining head 15, the swivel part 14, and the arm part 13, the temperature rise is prevented. This can prevent the life from being shortened.
[0029]
In this embodiment, the surface of the machining head, the swivel unit, and the arm unit is mirror-finished, but the other part of the housing of the processing machine (for example, the rail or leg housing) is mirror-finished. Also good. In the present embodiment, a laser processing machine is taken as an example of the processing machine, but the present invention can also be applied to other processing machines.
[0030]
FIG. 4 is a view showing another embodiment of a processing machine (laser processing machine) according to the present invention. A side view of the processing head 15 of the laser processing machine 10A and its peripheral portion is shown in a cross-sectional view of the heating furnace 30. Together with An arrow D in the figure indicates the traveling direction of the laser beam. The other arrows in the figure indicate the traveling direction of radiant heat.
[0031]
Unlike the laser processing machine 10 shown in FIGS. 1 to 3, the laser processing machine 10 </ b> A has a reflecting plate 18 attached to the processing head 15. The reflection plate 18 has a flat plate shape and is provided so as to go around the axis of the processing head 15. The reflecting plate 18 has a front surface 18a finished in a mirror shape so that the radiant heat from the opening 31 can be reflected forward. The other structure of the laser processing machine 10A is the same as that of the laser processing machine 10 shown by FIGS. That is, the laser processing machine 10A is also mirror-finished on the surface of the housing of the processing head 15, the surface of the housing of the swivel unit 14, and the surface of the housing of the arm unit 13.
[0032]
FIG. 5 is a cross-sectional view of the processing head 15 and its peripheral portion of the laser processing machine 10A, together with a cross-sectional view in the vicinity of the opening 31 of the heating furnace 30. In the figure, the internal mechanism of the laser beam machine 10A is omitted. The arrows in the figure indicate the traveling direction of radiant heat.
[0033]
In this laser processing machine 10A, since the front surface 18a of the reflector 18 is mirror-finished, the radiant heat from the opening 31 is reflected by the front surface 18a of the reflector 18 to the front of the processing head 15, that is, in the heating furnace 30. Proceed in the direction to return to. Further, the surface of the housing of the processing head 15 is mirror-finished, and even if the radiant heat is reflected backward on the surface of the housing of the processing head 15, it is reflected further in the direction toward the opening 31 by the front surface 18a of the reflecting plate 18. . The radiant heat that is reflected and goes into the heating furnace 30 heats the inside of the heating furnace 30. Thus, not only the temperature rise of the laser beam machine 10A due to radiant heat can be prevented, but also the temperature drop of the heating furnace 30 as a radiant heat source can be prevented.
[0034]
In the present embodiment, mirror finishing is also applied to the surfaces of the housings of the machining head, the swivel unit, and the arm unit. However, when the reflecting member is provided, it is not always necessary to apply a mirror finish to these housings. In the case where the reflecting member is provided, it is particularly effective for preventing the processing head from rising in temperature if at least a portion of the surface of the housing of the processing head is mirror-finished in front of the reflecting member. In the present embodiment, a laser processing machine is taken as an example of the processing machine, but the present invention can also be applied to other processing machines.
[0035]
FIG. 6 is a view showing still another embodiment of a processing machine (laser processing machine) according to the present invention. A side view of the processing head 15 of the laser processing machine 10B and its peripheral portion is shown in a cross section of the heating furnace 30. It is shown with a figure. An arrow D in the figure indicates the traveling direction of the laser beam. The other arrows in the figure indicate the traveling direction of radiant heat.
[0036]
FIG. 7 is a cross-sectional view of the processing head 15 and its peripheral portion of the laser processing machine 10B, together with a cross-sectional view in the vicinity of the opening 31 of the heating furnace 30. In the figure, the internal mechanism of the laser beam machine 10B is omitted. The arrows in the figure indicate the traveling direction of radiant heat.
[0037]
In this laser beam machine 10B, unlike the laser beam machine 10A shown in FIGS. 4 to 5, the reflector 19 attached to the machining head 15 is formed in a shape such that the front surface 19a is concave. The reflecting plate 19 is also provided so as to go around the axis of the processing head 15. The front surface 19a of the reflecting plate 19 is finished in a mirror shape so that the radiant heat from the opening 31 can be reflected in front of the processing head 15. Further, the front surface 19a of the reflecting plate 19 forms a substantially parabolic rotation surface. The focal point F of the parabolic rotation surface is on the axis L of the machining head 15. The structure of the laser beam machine 10B other than the reflector 19 is the same as that of the laser beam machine 10 shown in FIGS. That is, also in the laser processing machine 10B, the surface of the housing of the processing head 15, the surface of the housing of the swivel unit 14, and the surface of the housing of the arm unit 13 are finished in a mirror shape.
[0038]
Since the front surface 19a of the reflection plate 19 is mirror-finished, the radiant heat from the opening 31 is reflected by the front surface 19a of the reflection plate 19 and proceeds in the direction of returning to the front of the processing head 15, that is, into the heating furnace 30. Further, since the surface of the housing of the processing head 15 is mirror-finished, even if the radiant heat is reflected backward on the surface of the housing of the processing head 15, it is reflected in the direction toward the opening 31 further on the front surface 19a of the reflecting plate 19. . Since the front surface 19a of the reflecting plate 19 is concave, the radiant heat reflected by the reflecting plate 19 returns efficiently into the heating furnace 30 without being diffused around the opening 31. Therefore, it is more effective in preventing temperature drop in the heating furnace 30.
[0039]
In addition, since the front surface 19a has a substantially parabolic rotation surface, the radiant heat that travels parallel to the axis L of the processing head 15 and is applied to the reflection plate 19 is reflected by the reflection plate 19 and focused on the parabolic rotation surface. Collected by F. Therefore, when the workpiece W is placed so that the machining location coincides with the focal point F, the machining location can be heated by the radiant heat concentrated by the reflector 19. The stronger the radiant heat that leaks from the opening 31, the greater the degree of heating of the workpiece W by the reflector 19.
[0040]
As described above, the focal point F of the parabolic rotation surface is on the axis L of the machining head 15. The focal point of the laser beam and the focal point F of the parabolic rotation surface are substantially coincident. Therefore, the reflecting plate 19 assists the processing head 15 and heats the workpiece W. Therefore, the output of the laser beam from the machining head 15 may be small, and a laser oscillator having a low output can be adopted. That is, the initial cost and running cost of the processing machine can be reduced.
[0041]
In the present embodiment, a laser processing machine is taken as an example of a processing machine, but the present invention can also be applied to other processing machines.
[0042]
FIG. 8 is a view showing still another embodiment of a processing machine (laser processing machine) according to the present invention, in which a sectional view of the processing head 15 and its peripheral portion of the laser processing machine 10C is cut along the horizontal plane of the heating furnace 30. It is shown with the cross-sectional view. The arrows other than the arrows E1 and E2 in the figure indicate the traveling direction of the radiant heat.
[0043]
In this laser beam machine 10C, a reflection plate 20 as a reflection member is attached to the machining head 15 in the same manner as the laser beam machine 10B shown in FIGS. The front surface 20a of the reflecting plate 20 has a concave shape and a substantially parabolic rotation surface, and is finished in a mirror shape. However, unlike the laser beam machine 10B shown in FIGS. 6 to 7, the focal point F2 of the parabolic rotation surface of the front surface 20a of the reflector 20 is not on the axis L of the machining head 15, but away from the axis L. Is located. The focal point F1 of the laser beam from the machining head 15 and the focal point F2 of the parabolic rotation surface are spaced apart along the machining direction on the workpiece W. The other structure of the laser beam machine 10C is the same as that of the laser beam machine 10B shown in FIGS.
[0044]
In the laser processing machine 10C, when the work W conveyed in the heating furnace 30 comes to the front of the processing machine 10C, the work W is stopped and the work W is processed while controlling the movement of the processing head 15. The processing head 15 processes the processing portion of the workpiece W while moving in the direction of the arrow E1 in FIG. The processed portion of the workpiece W is heated by the radiant heat from the reflecting plate 20 prior to the irradiation of the laser beam. Although the processing location of the workpiece W cannot be raised to the processing temperature only by heating from the reflection plate 20, the temperature is higher than other locations of the workpiece W (locations that are not irradiated with radiant heat from the reflection plate 20). Can be. Therefore, the machining part of the workpiece W is preheated by the reflecting plate 20 before the main machining by the laser beam is performed. Therefore, the workpiece W can be sufficiently preheated even if the temperature in the heating furnace 30 is not so high. For this reason, the running cost of the heating furnace 30 can be reduced.
[0045]
Further, the machining portion of the workpiece W may be machined by moving the machining head in the direction of arrow E2 in FIG. The processed portion of the workpiece W is heated by the radiant heat from the reflecting plate 20 after being subjected to main processing with laser light. That is, the workpiece W is gradually cooled by the reflecting plate 20. Therefore, the workpiece W can be sufficiently cooled even if the temperature in the heating furnace 30 is not so high. For this reason, the running cost of the heating furnace 30 can be reduced.
[0046]
In the present embodiment, a laser processing machine is taken as an example of a processing machine, but the present invention can also be applied to other processing machines.
[0047]
FIG. 9 is a view showing still another embodiment of the processing machine according to the present invention, and shows a cross-sectional view of the processing head of the processing machine 10D and its peripheral portion together with a cross-sectional view of the heating furnace 30. The arrows in the figure indicate the traveling direction of radiant heat. Thus, the processing machine 10D is installed in the vicinity of the heating furnace 30, and processes the workpiece W in the heating furnace 30.
[0048]
The processing head of the processing machine 10D is composed of a reflecting plate 21 as a reflecting member, and does not include a mechanism for irradiating laser light. The reflector 21 reflects radiant heat leaking from the opening 31 of the heating furnace 30. The reflection plate 21 has a mirror-like front surface 21a so that radiant heat irradiated from the front can be reflected forward. The shape of the front surface 21a is a concave surface that forms a substantially parabolic rotation surface. Therefore, the radiant heat irradiated from the front can be collected at the focal point F3 of the parabolic rotation surface by reflection. The reflection plate 21 is controlled to move so that the focal point F3 moves along the machining location on the workpiece W. The machining part of the workpiece W is heated by radiant heat and rises to the machining temperature. That is, the workpiece W is processed by the radiant heat from the reflecting plate 21.
[0049]
The processing machine 10D does not require expensive and complicated equipment such as a laser oscillator. Also, maintenance such as adjustment of the optical axis of the laser beam is unnecessary. Therefore, the processing machine can be configured at low cost, and the running cost is low. In addition, labor required for maintenance can be reduced.
[0050]
FIG. 10 shows a case where the reflecting plate 21 of the processing machine 10D has turned to an unplanned direction. The arrows in the figure indicate the traveling direction of radiant heat. For example, if the processing machine 10D runs out of control and the reflecting plate 21 faces in a direction other than the opening 31 as shown in this figure, the projected area of the reflecting plate 21 with respect to the opening surface of the opening 31 becomes small, and reflection The amount of radiant heat applied to the plate 21 is reduced. Therefore, even if the radiant heat reflected by the reflecting plate 21 is collected at a point, the equipment at that point and the worker there are not subjected to strong heating. That is, even if the processing machine 10D runs out of control or an error occurs in the control program of the processing machine 10D, it is safe.
[0051]
FIG. 11 is a view showing still another embodiment of a processing machine (laser processing machine) according to the present invention, wherein (a) is a rear view and (b) is a side view. FIG. 12 is a partial cross-sectional view of the turning portion 44 of the laser beam machine 40. As shown in FIG. The laser processing machine 40 is installed in the vicinity of the heating furnace 30, and in FIG. 11B, the heating furnace 30 is also shown together with the laser processing machine 40. The heating furnace 30 has the same configuration as the heating furnace 30 shown in FIGS.
[0052]
The laser processing machine 40 has two leg portions 41, a rail portion 42 spanned on the leg portions 41, an arm portion 43, a turning portion 44, and a machining head 45. The leg portion 41 is fixed to the floor surface. The arm portion 43 can move in the direction of the arrow X and the direction of the arrow Y in the drawing with respect to the rail portion 42. Further, the turning portion 44 can turn in the direction of the arrow G in the drawing with respect to the arm portion 43, and the machining head 45 can change the angle in the direction of the arrow H in the drawing with respect to the turning portion 44. It has become. The angle of the machining head 45 with respect to the turning unit 44 is changed by a motor 44a or the like incorporated in the turning unit 44. That is, as shown in FIG. 12, a motor 44a is incorporated in the turning portion 44. Further, the machining head 45 is pivoted with respect to the turning portion 44. A pulley 44b attached to the rotation shaft of the motor 44a is connected to a pulley 45b attached to the pivot shaft of the machining head 45 by a belt 48. Therefore, by controlling the rotation of the motor 44a, the machining head 45 is rotated in the direction of the arrow H in the figure with respect to the turning portion 44. The movement of the arm unit 43, the turning of the turning unit 44, and the rotation of the motor 44a are controlled by a control unit (not shown).
[0053]
The laser beam is introduced from the laser beam inlet 46, guided to the machining head 45 by a mirror incorporated in the laser beam machine 40, passes through the lens in the machining head 45, and is output from the tip of the machining head 45. Is done. An arrow D in FIG. 11B indicates the traveling direction of the laser light.
[0054]
In the laser processing machine 40, similarly to the laser processing machine 10 shown in FIGS. 1 to 3, the rail part 42, the arm part 43, the turning part 44, and the processing head 45 are respectively provided with internal mechanisms such as a drive system and an optical system. Is covered with a housing. The surface of the housing of the processing head 45, the surface of the housing of the turning portion 44, and the surface of the housing of the arm portion 43 are finished in a mirror shape. Therefore, even if the radiant heat leaked from the opening 31 of the heating furnace 30 is applied to the processing head 45, the swivel part 44, and the arm part 43, the radiant heat is reflected on the surfaces of the housings. Therefore, it is possible to prevent the temperature of the internal mechanism of the laser beam machine 40 from rising significantly due to radiant heat.
[0055]
FIG. 13 is a view showing still another embodiment of the processing machine (laser processing machine) according to the present invention, and shows a side view of the processing head 45 of the laser processing machine 40A and its peripheral portion. An arrow D in the figure indicates the traveling direction of the laser beam. The other arrows in the figure indicate the traveling direction of radiant heat.
[0056]
The laser processing machine 40A is different from the laser processing machine 40 shown in FIGS. The other structure of the laser beam machine 40A is the same as that of the laser beam machine 40 shown in FIGS. The reflector 18 of the laser beam machine 40A has the same structure as the reflector plate 18 of the laser beam machine 10A shown in FIGS. That is, the reflecting plate 18 of the laser processing machine 40A is also flat and is provided so as to go around the axis of the processing head 45. The front surface 18a is finished in a mirror shape so that the radiant heat from the opening 31 of the heating furnace 30 can be reflected forward.
[0057]
Therefore, similarly to the laser beam machine 10A of FIGS. 4 to 5, not only the temperature rise of the laser beam machine 40A due to radiant heat can be prevented, but also the temperature drop of the heating furnace 30 as a radiant heat source can be prevented.
[0058]
FIG. 14 is a view showing still another embodiment of the processing machine (laser processing machine) according to the present invention, and shows a side view of the processing head 45 of the laser processing machine 40B and its peripheral portion. An arrow D in the figure indicates the traveling direction of the laser beam. The other arrows in the figure indicate the traveling direction of radiant heat.
[0059]
A reflecting plate 19 is attached to the processing head 45 of the laser processing machine 40B. The structure of the laser beam machine 40B other than the reflector 19 is the same as that of the laser beam machine 40 shown in FIGS. The reflecting plate 19 of the laser beam machine 40B has the same structure as the reflecting plate 19 of the laser beam machine 10B shown in FIGS. That is, the reflector 19 of the laser beam machine 40B is also formed in a shape such that the front surface 19a is concave, and is provided so as to go around the axis of the machining head 45. The front surface 19a of the reflecting plate 19 is finished in a mirror shape so that the radiant heat from the opening 31 of the heating furnace 30 can be reflected in front of the processing head 45. Further, the front surface 19a of the reflecting plate 19 forms a substantially parabolic rotation surface. The focal point F of the parabolic rotation surface is on the axis L of the machining head 15.
[0060]
Therefore, the radiant heat reflected by the reflecting plate 19 can be efficiently returned into the heating furnace 30 without being diffused around the opening 31 of the heating furnace 30 as in the laser processing machine 10B of FIGS. Further, the reflector 19 can heat the workpiece W by assisting the processing head 45.
[0061]
FIG. 15 is a view showing still another embodiment of the processing machine (laser processing machine) according to the present invention, and shows a cross-sectional view of the processing head 45 of the laser processing machine 40C and its peripheral portion cut along a horizontal plane. is there. In this figure, the internal mechanisms of the turning unit 44 and the machining head 45 are omitted. The arrows in the figure indicate the traveling direction of radiant heat.
[0062]
The reflection plate 20 is attached to the processing head 45 of the laser processing machine 40C. The structure of the laser beam machine 40C other than the reflector 20 is the same as that of the laser beam machine 40 shown in FIGS. The reflector 20 of the laser beam machine 40C has the same structure as the reflector plate 20 of the laser beam machine 10C shown in FIG. That is, the front surface 20a of the reflector 20 of the laser processing machine 40C has a concave shape and a substantially parabolic rotation surface, and is finished in a mirror shape. The focal point F2 of the parabolic rotation surface of the front surface 20a of the reflecting plate 20 is not on the axis L of the processing head 45 but is located away from the axis L. The focal point F1 of the laser beam from the machining head 45 and the focal point F2 of the parabolic rotation surface are spaced along the machining direction on the workpiece W.
[0063]
Therefore, the processing part of the workpiece W is preheated by radiant heat from the reflection plate 20 before the main processing by the laser beam is performed, or is heated by radiant heat from the reflection plate 20 after the main processing by the laser beam is performed. And can be gradually cooled.
[0064]
FIG. 16 is a view showing still another embodiment of the processing machine according to the present invention, and is a side view showing a processing head and its peripheral part of the processing machine 40D. The arrows in the figure indicate the traveling direction of radiant heat. Thus, the processing machine 40D is installed in the vicinity of the heating furnace 30, and processes the workpiece W in the heating furnace 30.
[0065]
In the processing machine 40D, similarly to the processing machine 10D shown in FIGS. 9 to 10, the processing head is composed of the reflecting plate 21 as a reflecting member, and does not include a mechanism for irradiating laser light. The reflecting plate 21 of the processing machine 40D has the same structure as the reflecting plate 21 of the processing machine 10D shown in FIGS. That is, the reflecting plate 21 of the processing machine 40D reflects the radiant heat leaking from the opening 31 of the heating furnace 30, but its front surface 21a so that the radiant heat irradiated from the front can be reflected forward. Is mirror-finished. The shape of the front surface 21a is a concave surface that forms a substantially parabolic rotation surface. The reflecting plate 21 is controlled to move so that the focal point F3 of the parabolic rotation surface moves along the machining location on the workpiece W, and raises the machining location of the workpiece W to the machining temperature by radiant heat.
[0066]
Therefore, the processing machine 40D can also be configured at a low cost as in the processing machine 10D of FIGS. 9 to 10, and the running cost is low. In addition, labor required for maintenance can be reduced. Furthermore, even if the processing machine 40D runs out of control or an error occurs in the control program of the processing machine 40D, it is safe.
[0067]
The present invention has been described above based on various embodiments. In the above-described embodiment, since the front surface of the reflecting member has a substantially parabolic rotating surface in order to concentrate radiant heat at a predetermined location by reflection, the degree of concentration is extremely high. However, the shape of the front surface of the reflecting member may be other shapes such as a hyperbolic rotation surface and a spherical shape. If the radiant heat is concentrated by such a shape, the degree of concentration cannot be increased as much as the parabolic rotating surface shape, but the heating range can be widened. Further, since the spherical shape is a shape that can be easily processed, the manufacturing cost can be reduced.
[0068]
【The invention's effect】
The present invention is implemented in the form described above, and has the following effects.
(1) If at least a part of the surface of the housing is mirror-like, the temperature rise due to the radiant heat of the processing machine can be minimized.
(2) When the surface of the portion of the housing that accommodates the optical system is finished in a mirror shape, expansion due to a temperature rise of the optical system can be prevented, and the accuracy of the optical system can be maintained.
(3) When the processing machine is installed in the vicinity of the furnace having the opening, the radiant heat from the opening of the furnace is effectively reflected, and the temperature rise of the processing machine due to the radiant heat can be minimized.
(4) If the surface of the housing of the processing head is finished in a mirror surface, it is particularly effective for preventing the temperature rise of the processing machine, and it is possible to prevent a decrease in accuracy due to expansion of the internal mechanism of the processing head.
(5) Providing the reflecting member is effective in preventing the temperature rise of the processing machine, and can also prevent the temperature of the radiant heat source from decreasing.
(6) If at least a portion of the surface of the housing of the machining head is finished in a mirror-like shape, it is particularly effective for preventing the machining head from rising in temperature.
(7) When the front surface of the reflecting member is concave, the radiant heat can be more efficiently returned to the radiant heat source by the reflecting plate.
(8) When a reflecting member capable of concentrating parallel radiant heat irradiated from the front at a predetermined location by reflection is provided, the workpiece can be heated by collecting the radiant heat at the predetermined location.
[0069]
In particular, when the predetermined location is on the axis of the machining head, the workpiece can be heated with the assistance of the machining head.
[0070]
In particular, when the predetermined portion is located at a position away from the axis of the machining head, the workpiece can be heated for preheating or slow cooling.
[0071]
In particular, when the reflecting member itself is used as a processing head for performing main processing, a very safe processing machine having a simple structure can be configured.
[0072]
In particular, when the shape of the front surface of the reflecting member is a concave surface that forms a substantially parabolic rotation surface, the concentration of radiant heat can be made extremely high.
[Brief description of the drawings]
FIG. 1 is a three-side view showing a processing machine (laser processing machine), where (a) is a rear view, (b) is a side view, and (c) is a plan view.
FIG. 2 is a perspective view of a part of a laser beam machine and a heating furnace.
FIG. 3 is a side view of a processing head of a laser beam machine and a peripheral portion thereof, together with a cross-sectional view of a heating furnace.
FIG. 4 is a view showing another embodiment of a processing machine (laser processing machine), and is a view showing a side view of a processing head of the laser processing machine and its peripheral portion together with a cross-sectional view of a heating furnace.
FIG. 5 is a view showing a sectional view of a machining head of a laser beam machine and its peripheral portion together with a sectional view in the vicinity of an opening of a heating furnace.
FIG. 6 is a view showing still another embodiment of a processing machine (laser processing machine), and is a view showing a side view of a processing head of the laser processing machine and its peripheral portion together with a cross-sectional view of a heating furnace. .
FIG. 7 is a view showing a sectional view of a machining head of a laser beam machine and its peripheral portion together with a sectional view in the vicinity of an opening of a heating furnace.
FIG. 8 is a view showing still another embodiment of a processing machine (laser processing machine) according to the present invention, and is a cross-sectional view of a processing head of the laser processing machine and a peripheral portion thereof, in which a heating furnace is cut along a horizontal plane. It is the figure shown with the figure.
FIG. 9 is a view showing still another embodiment of the processing machine according to the present invention, and is a view showing a cross-sectional view of the processing head of the processing machine and its peripheral portion together with a cross-sectional view of the heating furnace.
FIG. 10 is a cross-sectional view of the reflector and the heating furnace when the reflector of the processing machine is directed in an unplanned direction.
11A and 11B are views showing still another embodiment of a processing machine (laser processing machine), where FIG. 11A is a rear view of the laser processing machine, and FIG. 11B is a side view.
FIG. 12 is a partial cross-sectional view of a turning unit of a laser beam machine.
FIG. 13 is a view showing still another embodiment of a processing machine (laser processing machine), and shows a side view of a processing head of the laser processing machine and a peripheral portion thereof along with a cross-sectional view in the vicinity of an opening of a heating furnace. It is.
FIG. 14 is a view showing still another embodiment of the processing machine (laser processing machine), and shows a side view of the processing head of the laser processing machine and its peripheral portion together with a sectional view in the vicinity of the opening of the heating furnace. It is.
FIG. 15 is a view showing still another embodiment of a processing machine (laser processing machine), and is a view showing a cross-sectional view of a processing head of the laser processing machine and its peripheral portion together with a cross-sectional view of a heating furnace. is there.
FIG. 16 is a view showing still another embodiment of the processing machine, and is a view showing a side view of the processing head and its peripheral portion together with a sectional view in the vicinity of the opening of the heating furnace.
[Explanation of symbols]
M1, M2, M3, M4 mirror
R lens
S mounting table
W Work
10,10A, 10B, 10C Laser processing machine
10D processing machine
11 legs
12 Rail section
13 Arm
14 Turning part
15 Processing head
16 Laser beam entrance
17 bellows
18, 19, 20, 21 Reflector
18a, 19a, 20a, 21a front
30 Heating furnace
31 opening
32 Workpiece inlet
33 lid
40,40A, 40B, 40C Laser processing machine
40D processing machine
41 legs
42 Rail section
43 Arm
44 Turning part
44a motor
44b pulley
45 Processing head
45b pulley
46 Laser beam entrance
48 belts

Claims (6)

A laser processing machine installed in the vicinity of a heating furnace having an opening,
  The laser processing machine has a processing head that outputs laser light from its tip,
  The processing head irradiates the workpiece in the heating furnace with laser light through the opening,
  Radiation heat radiated from the opening of the heating furnace is irradiated to the processing head,
  The processing head includes an optical system and a housing that covers the optical system,
  A laser processing machine in which a portion of the surface of the housing irradiated with the radiant heat from the opening is finished in a mirror shape. A laser processing machine installed in the vicinity of a heating furnace having an opening,
  The laser processing machine has a processing head that outputs laser light from its tip,
  The processing head irradiates the workpiece in the heating furnace with laser light through the opening,
  The processing head is provided with a reflecting member so as to circulate around the axis of the processing head,
  A laser processing machine configured to reflect radiant heat radiated from the opening of the heating furnace toward the opening by the reflecting member. The processing head includes an optical system and a housing that covers the optical system,
  The laser processing machine according to claim 2, wherein a portion of the surface of the housing that protrudes toward the opening rather than a surface of the reflecting member facing the opening is finished in a mirror shape. 4. The laser processing machine according to claim 2, wherein a surface of the reflecting member facing the opening is finished in a mirror shape. The laser processing machine according to claim 4, wherein a surface of the reflecting member facing the opening is concave . A laser processing machine installed in the vicinity of a heating furnace having an opening,
  The laser processing machine has a processing head that outputs laser light from its tip,
  The processing head irradiates the workpiece in the heating furnace with laser light through the opening,
  The processing head processes the workpiece while moving relative to the workpiece,
  The processing head is provided with a reflecting member so as to circulate around the axis of the processing head,
  The surface of the reflecting member facing the opening is finished in a mirror shape,
  Radiant heat radiated from the opening of the heating furnace is reflected toward the opening by the surface of the reflecting member facing the opening,
  The surface of the reflecting member facing the opening is shaped so that the reflected radiant heat can be concentrated at a predetermined location in the heating furnace through the opening.
  The predetermined position is a laser processing machine which is a distance from the axis of the processing head along a moving direction of the processing head with respect to the workpiece.

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