KR101404670B1 - turning operation apparatus for brittle material - Google Patents

Abstract

The present invention relates to a processing apparatus for brittle materials which can irradiate a laser beam on a workpiece to preheat an area to be processed during a turning operation on brittle materials such as a rock and ceramic. According to the present invention, the processing apparatus for brittle materials includes a rotary driving part which clamps and rotates the workpiece made of a brittle material; a processing part which includes a processing tool that contacts and processes the workpiece rotated by the rotary driving part; and a laser irradiation part which is joined to the processing part and irradiates a laser beam to preheat the workpiece.

Description

BACKGROUND ART [0002] Turning apparatus for brittle material

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a brittle material processing apparatus, and more particularly, to a brittle material processing apparatus capable of preheating a workpiece by irradiating a workpiece with a laser beam during turning of a brittle material such as a stone or a ceramic.

Generally, materials with high brittleness such as ceramics, stones, cast iron, etc. are subject to breakage due to the characteristics of materials when turning, milling or boring using a processing tool. Therefore, in order to solve such a problem, a preheating method of applying a laser to a machining surface of a brittle material in advance to preheat the machining surface and then machining the machining surface using a machining tool has been applied.

However, in the prior art, in the case of apparatuses for preheating and processing workpieces using a laser, usually, a separate laser irradiation apparatus is provided so as to be adjacent to the workpiece so as to irradiate laser light for heating toward the workpiece.

In the case of such a prior art processing apparatus, since a fixing means for installing and fixing a separate laser beam for irradiating a laser is provided, the configuration of the apparatus is complicated and the shape of the workpiece changes as processing progresses. There has been a problem in that it is not easy to change the irradiation position in response to the mold deformation of such a work.

Registration No. 10-1135436: Method of processing brittle material substrate Registration No. 10-1200788: Method of processing brittle material substrate and processing apparatus

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is an object of the present invention to provide a laser processing apparatus and a laser processing method, And to provide a machining apparatus for a brittle material which is capable of performing brittle material processing.

In order to accomplish the above object, the present invention provides a brittle material processing apparatus comprising a rotation driving unit for clamping and rotating a workpiece as a brittle material, and a processing tool for processing the workpiece in contact with the workpiece rotated by the rotation drive unit And a laser irradiation unit coupled to the processing unit to irradiate a laser beam for preheating the workpiece.

The laser irradiating unit may include a laser generator, an optical fiber cable for transmitting the laser beam irradiated from the laser generator, and a housing installed at an end of the optical fiber cable and irradiating the laser beam to a preheating position of the workpiece .

The machining tool may include a machining tip in contact with the workpiece, a support member detachably coupled to the tool holder, and the housing being adapted to be attached to the support member.

Wherein the housing is provided slidably along the longitudinal direction on the support member, and the processing tool further includes a forward / backward driving unit formed on the supporting member to forward / backward move the housing in the forward / backward direction, A rack mounted on a lower portion of the housing; a pinion which is engaged with the rack and is rotatably mounted on the support member; a worm wheel mounted on a rotary shaft of the pinion and rotated integrally with the pinion; And a tool engagement groove is formed on one side of the worm wheel so that the worker can rotate the worm by using a tool.

The laser irradiation unit includes an extension cable formed of an optical fiber so as to extend toward the front of the housing to guide laser light and irradiate a laser beam at an end thereof and a gooseneck member that surrounds the extension cable and fixes an extension of the extension cable .

The brittle material processing apparatus according to the present invention has an advantage that a difficult-to-break material having high brittleness such as ceramic, stone, and cast iron can be easily processed in turning.

In addition, since the laser irradiation unit for irradiating the laser for preheating the workpiece is coupled to the machining tool and driven together with the machining tool, the laser beam is irradiated to the machining tool at a predetermined position, simplifying the structure and advantageously enabling efficient preheating .

1 is a perspective view showing an embodiment of a brittle material processing apparatus according to the present invention,
Fig. 2 is a side view of the brittle material processing apparatus of Fig. 1,
3 is an exploded perspective view showing another embodiment of the brittle material processing apparatus,
4 is a perspective view showing still another embodiment of a brittle material processing apparatus.

Hereinafter, a brittle material processing apparatus according to the present invention will be described in more detail with reference to the accompanying drawings.

1 and 2, a first embodiment of a brittle material processing apparatus 100 is shown. The brittle material processing apparatus 100 of the present embodiment includes a rotation driving unit 110 for rotating the workpiece 10 as a brittle material for turning and a workpiece 10 rotated by being clamped by the rotation driving unit 110 A laser irradiation unit 130 installed on the processing tool 122 for irradiating a laser beam for preheating the workpiece 10; And a temperature sensor 160 installed at a position adjacent to the workpiece 10 and measuring the temperature of the workpiece 10 to be heated.

Although not shown, the rotation driving unit 110, the machining unit 120, the temperature sensor 160, and the like for rotating the workpiece 10, which is an object to be processed, are provided on one side of the bed, Respectively.

The rotation driving unit 110 is a rotating body rotated by a motor and is configured to clamp the workpiece 10 at one side thereof so that the workpiece 10 is rotated together with the workpiece 10 clamped.

The machining unit 120 is a tool for machining while cutting the workpiece 10 in contact with the outer surface of the rotating workpiece 10 and includes a tool rest 121 provided on the bed and a tool rest And a processing tool 122.

The tool rest 121 is detachably coupled to the machining tool 122 such as a conventional lathe and includes a workpiece 10 so that the machining tool 122 described below contacts or separates the workpiece 10. [ As shown in Fig.

The processing tool 122 includes a support member 123 detachably coupled to the tool rest 121 and a machining tip 124 coupled to an end of the support member 123.

The support member 123 extends from the tool rest 121 to the workpiece 10 clamped to the rotary drive unit 110 and the machining tip 124 is provided at the end of the support member 123 to support the workpiece 10 so that the workpiece 10 is cut. The machining tip 124 is detachably coupled to the support member 123 so that it can be replaced when worn.

The laser irradiation unit 130 is provided on the support member 123 to preheat the machined surface of the workpiece 10 by irradiating the surface of the workpiece 10 with a laser.

Workpieces 10 of brittle materials such as ceramics, stones and cast iron can be cracked during processing, so laser is applied for preheating to improve processing efficiency.

The laser irradiating unit 130 includes a laser generator (not shown) for generating a laser beam, an optical fiber 131 for transmitting a laser generated from the laser generator, and an optical fiber 131 formed at an end of the optical fiber 131 and coupled to the support member 123 (Not shown).

The housing 132 is coupled to the support member 123 to fix the end of the optical fiber 131 so that the laser can be irradiated toward a certain point.

Since the housing 132 for irradiating the laser beam L is provided on the support member 123, the laser irradiation unit 130 of the present embodiment is provided with a movable tool for advancing or retreating to move the workpiece 10 The laser beam L can be irradiated to the machining tip 124 at a predetermined position as the housing 132 is driven together. That is, as the machining of the workpiece 10 is performed, the machining tool 122 advances Or lifted or lowered, the irradiation point at which the laser beam L is irradiated to the machining tip 124 is kept constant while the housing 132 is moved forward, elevated or lowered together.

The temperature sensor 160 is for measuring the temperature of the workpiece 10.

The temperature of the workpiece 10 gradually rises as the laser beam L is continuously irradiated on the workpiece 10 by the laser irradiation unit 130. When the temperature of the workpiece 10 is raised to a certain level or more, A temperature sensor 160 is provided to stop the driving of the laser irradiation unit 130 when the temperature of the workpiece 10 rises above the set reference value.

FIG. 3 shows another embodiment of the laser irradiation unit 130. FIG.

The laser irradiation unit 130 of the present embodiment further includes a forward / backward driving unit 140 that can drive the housing 132 forward and backward with respect to the supporting member 123.

The support member 123 is provided with guide rails 141 along the longitudinal direction of the support member 123 facing the workpiece 10 and the housing 132 is slidable along the guide rails 141 Respectively.

The advance and retreat drive unit 140 includes a rack 142 provided in the housing 132, a pinion 143 rotatably coupled to the support member 123 to be engaged with the rack 142, A worm wheel 146 mounted on the rotation shaft 144 of the pinion 143 and a worm 145 coupled to the worm wheel 146 rotatably and coupled to the support member 123, ).

The worm 145 has a tool engagement groove formed at one side thereof to rotate the worm 145 through a rotary tool 147 such as a screwdriver so that the operator can use the rotary tool 147 to move the worm 145 in one direction It can be rotated in the other direction.

When the worm 145 rotates, the worm wheel 146 engaged with the worm 145 rotates. Since the worm wheel 146 is coaxial with the pinion 143, the pinion 143 rotates while rotating the housing 132 To the front and rear.

Sliding and driving the housing 132 in this way is for focusing the irradiation of the laser beam L. [ In the case of a conventional laser irradiator, the housing 132 includes a lid screwed to the body so as to change the position of the focusing lens. In this case, the structure of the housing 132 is complicated and difficult to precisely focus . Therefore, the operator can finely move the housing 132 forward and backward through the worm 145 and the worm wheel 146.

Fig. 4 shows another embodiment of the laser irradiation unit 130. Fig.

The housing 132 is provided on the tool rest 121 and an extension cable 150 made of an optical fiber is extended toward the workpiece 10 so that the laser beam L passes through the housing 132 And a gooseneck member 151 which surrounds the extension cable 150 is provided as a shape maintaining means for maintaining an extension shape of the extension cable 150.

It is necessary to change the irradiation position for irradiating the laser according to the shape of the workpiece 10 and the processing conditions such as the position and size of the processing tip 124. In this embodiment, the laser beam L passes through If the extension cable 150 that can be irradiated is extended toward the workpiece 10 and the extension cable 150 can be kept bent or folded by the gooseneck member 151, The worker can freely select a position where irradiation can be performed efficiently, and the extension cable 150 is held in a folded state by the gooseneck member 151.

The brittle material processing apparatus 100 according to the present invention described above can improve the processing efficiency of the brittle material by irradiating the surface of the brittle material with a laser beam to preheat the laser beam L, It is possible to keep the irradiation point of the light source constant.

 While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is evident that many alternatives, modifications and variations will be apparent to those skilled in the art. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

10; Workpiece
100; Processing equipment for brittle materials
110; The rotation-
120; Processing section
121; Tool stand 122; Processing tool
123; A support member 124; Processing Tips
130; Laser irradiation unit
131; Optical fiber 132; housing
L; Laser beam
140; The forward /
141; Guide rails 142; Rack
143; Pinion 144; Rotating shaft
145; Worm 146; Worm wheel
147; Rotary tool
150; Extension cable 151; Goose neck member
160; temperature Senser

Claims (5)

delete delete A rotation driving unit for clamping and rotating the workpiece as a brittle material;
A machining portion including a machining tool for machining the workpiece in contact with the workpiece rotated by the rotation drive portion;
And a laser irradiation unit coupled to the machining unit to irradiate laser light for preheating the work,
The laser irradiation unit includes a laser generator, an optical fiber cable for transmitting the laser beam emitted from the laser generator, and a housing installed at an end of the optical fiber cable for irradiating the laser beam to a preheating position of the workpiece,
Wherein the machining tool includes a machining tip in contact with the workpiece, a support member detachably coupled to the machining tip and mounted to the tool base,
Wherein the housing is configured to be attached to the support member. The method of claim 3,
The housing is slidably installed along the longitudinal direction on the support member,
Wherein the processing tool further includes a forward / backward driving portion formed on the supporting member and capable of driving the housing in a backward and forward direction,
And a worm wheel which is installed on a rotary shaft of the pinion and rotates integrally with the pinion, and a worm wheel which is mounted on the rotary shaft of the pinion and rotates integrally with the pinion, And a worm having a tool engagement groove formed on one side of the support member so as to be engaged with the worm wheel and rotatably driven by a worker using a tool on one side thereof. The method of claim 3,
The laser irradiation unit includes an extension cable formed of an optical fiber so as to extend toward the front of the housing to guide laser light and irradiate laser light at an end thereof,
Further comprising a gooseneck member for surrounding the outside of the extension cable and fixing an extension of the extension cable.

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