JP6542591B2 - Machining apparatus and machining method - Google Patents

Description

  Embodiments of the present invention relate to a machining apparatus and a machining method.

  When manufacturing aircraft parts such as spars (ribs), small bones (ribs), skins (panels) (also referred to as skins) and stringers (stringers) by machining, transportation or corrosion protection of the aircraft parts after machining A tab is often provided for the purpose of utilizing it as an electrode for surface treatment such as treatment. If the machined article is provided with tabs, it is necessary to cut the tabs when assembling the machined article. Therefore, conventionally, a worker cuts a tab leaving excess meat using a jigsaw which is a hand tool (see, for example, Patent Document 1). The excess meat remaining after cutting of the tab is finished by sanding with a belton (belt sander).

JP, 2015-24489, A

  However, manual tab cutting results in variations in quality among workers. In particular, in the case of an aircraft part, the shape of the tab after cutting may be a curvilinear shape or a curved surface. In addition, finishing work of excess meat after cutting the tab leads to an increase in the labor of the worker. This is a common problem not only for aircraft parts but also for various parts involving tab cutting and finishing.

  Therefore, an object of the present invention is to enable easy cutting and finishing of tabs with better quality.

A machining apparatus according to an embodiment of the present invention includes a rotation mechanism, a guide member, a movement mechanism, and an attachment. The rotation mechanism holds and rotates the shank of the tool having the shank and the cutting portion. The guide member guides the movement of the tool in the direction perpendicular to the tool axis direction along the machined shape of the workpiece. In addition, the guide member has a guide surface which causes the non-rotational portion of the rotation mechanism, which moves with the tool, to slide linearly or non-linearly in only one direction. Moving mechanism, said guide member along said guide surface as a non-rotating portion is linearly or non-linearly slide, the first perpendicular to the tool relative to the tool axis direction along with the non-rotating part Manually moving in the direction, while freely sliding the tool in a second direction perpendicular to the tool axis direction without using a power source, along with the slide along the guide surface of the non-rotating part Let The mounting tool mounts the rotation mechanism, the guide member, and the movement mechanism on the workpiece.
A machining method according to an embodiment of the present invention is to manufacture a machined product using the machining device.
In the machining method according to an embodiment of the present invention, the tool is changed a plurality of times in the direction perpendicular to the tool axis direction while changing the position of the tool in the tool axis direction using the machining device. A machined product is manufactured by moving processing.

The front view which shows the structure of the machining apparatus which concerns on embodiment of this invention. The top view of the machining apparatus shown in FIG. The perspective view of the machining apparatus shown in FIG. The perspective view which looked at the machining apparatus shown in FIG. 1 from the back side. FIG. 3 is a cross-sectional view at position A-A showing a structural example of the rotation mechanism shown in FIG. 2; The perspective view which shows the example of a shape of the pinching member in the state which removed the disk type | mold clamp shown in FIG.

  A machining apparatus and a machining method according to an embodiment of the present invention will be described with reference to the attached drawings.

(Configuration and function)
1 is a front view showing the configuration of a machining apparatus according to an embodiment of the present invention, FIG. 2 is a top view of the machining apparatus shown in FIG. 1, FIG. 3 is a perspective view of the machining apparatus shown in FIG. FIG. 2 is a perspective view of the machining device shown in FIG. 1 as viewed from the back side.

  The machining device 1 is a device for attaching to a workpiece W which is an object to be machined by cutting, and performing a finishing process mainly using a tool T to cut a tab and remove an excess thickness. If the machining device 1 is configured by small components, the machining device 1 can also be configured as a hand tool that is easy to carry. Specifically, the machining device 1 can include at least the rotation mechanism 2, the movement mechanism 3, the guide member 4, and the attachment 5 as components.

  The rotation mechanism 2 is a device that holds and rotates the shank of the tool T. Therefore, as the tool T, one having a shank and a cutting edge is used. That is, instead of a cutter in which a cutting surface perpendicular to the rotational axis direction of the tool is formed like a side cutter, a tool T such as a solid type or tip end mill is used. Alternatively, a tapered end mill may be used. Accordingly, the cutting surface is formed substantially in the rotational axis direction of the tool T. That is, the cut surface or the finished surface is formed in the tool axial direction Tax of the tool T by the cutting process of the tab and removal of the excess thickness.

  The rotation mechanism 2 is a device that automatically rotates the tool T by a power source. Therefore, the rotation mechanism 2 has a motor 2A and a holder 2B. The output shaft of the motor 2A is coupled to the holder 2B. For this reason, the tool T can be rotated by holding the shank of the tool T with the holder 2B and rotating the output shaft of the motor 2A.

  A router is commercially available as a hand-held power tool for holding the shank of the tool T by the holder 2B and rotating the tool T by driving the motor 2A to process the outer shape of the workpiece W and the like. For this reason, a commercially available router can be used as the rotation mechanism 2. The tool T for a router is also called a bit. Also, small hand-held routers are also called hand routers.

  The moving mechanism 3 is a device for moving the tool T together with the rotating mechanism 2. The moving mechanism 3 is configured to be able to move the rotation mechanism 2 holding the tool T at least in a direction perpendicular to the tool axis direction Tax.

  For example, the moving mechanism 3 can be configured such that the rotating mechanism 2 holding the tool T can be linearly moved in one direction perpendicular to the tool axial direction Tax. In this case, since the drive shaft of the moving mechanism 3 is one axis, the structure of the moving mechanism 3 can be simplified. Therefore, machining that is supposed to be performed by the machining device 1 is effective in the case of machining in which the tool T is moved linearly.

  On the other hand, the moving mechanism 3 can also be configured such that the rotating mechanism 2 holding the tool T can be moved in two directions perpendicular to the tool axial direction Tax. In this case, it is possible to freely move the rotation mechanism 2 holding the tool T in a two-dimensional plane perpendicular to the tool axial direction Tax. That is, since the drive shaft of the moving mechanism 3 is two axes, the rotating mechanism 2 holding the tool T is linearly moved in an arbitrary direction in a two-dimensional plane perpendicular to the tool axial direction Tax. It is also possible to move non-linearly so as to draw a curvilinear or polygonal trajectory. For this reason, not only linear processing but nonlinear processing is possible, and the versatility of the machining device 1 can be improved.

  Furthermore, the moving mechanism 3 can also be configured such that the tool T can be moved in the tool axis direction Tax. The movement of the tool T in the tool axial direction Tax may be performed during the rotation operation of the tool T, or may be performed as positioning in the tool axial direction Tax before the rotation of the tool T.

  In order to enable the feed operation of the tool T in the tool axial direction Tax during the rotational movement of the tool T, processing using the bottom edge of the tool T such as an end mill or a drill, or to a processing position in the tool axial direction Tax The advancing operation of the tool T and the retreating operation from the processing position are possible. Therefore, it is possible to perform various machining such as drilling, grooving, pocketing, and step machining in which cutting is repeated by changing the cutting amount in the tool axial direction Tax.

  On the other hand, when it is possible to adjust the positioning of the tool T in the tool axial direction Tax, that is, the positions of the tip and cutting edge of the tool T, the feed operation of the tool T in the tool axial direction Tax during rotation is performed. Even if it can not be done, the positions of the tip of the tool T and the cutting edge in the tool axial direction Tax can be adjusted to an appropriate position without attaching and detaching the tool T to the holder 2B. In addition, if cutting is repeated while changing the positions of the tip of the tool T and the cutting edge in the tool axial direction Tax, it is possible to perform step processing.

  Thus, the drive shaft of the moving mechanism 3 can be arbitrarily determined in accordance with the application of the machining device 1. Therefore, the moving mechanism 3 may be provided with a tilt axis for tilting the rotation axis of the tool T or a rotation axis for rotating the rotation axis of the tilted tool T about the rotation axis before tilting. However, if the application of the machining device 1 is not processing the inclined surface or processing the curved surface, it is realistic to provide the moving mechanism 3 with linear axes orthogonal to each other from the viewpoint of simplifying the structure of the moving mechanism 3.

  That is, the moving mechanism 3 capable of spatially moving the tool T in three axial directions orthogonal to one another, and moving the tool T two-dimensionally in one direction perpendicular to the tool axial direction Tax and the tool axial direction Tax 3, the movement mechanism 3 capable of moving the tool T two-dimensionally in two directions perpendicular to each other and respectively perpendicular to the tool axial direction Tax, or only one direction perpendicular to the tool axial direction Tax It is practical to provide the machining device 1 with a moving mechanism 3 capable of moving the tool T linearly.

  The movement of the tool T in each axial direction may be automatically performed by using a power source such as a motor or the like, or may be performed without using the power source. In particular, if the operation other than the rotational operation of the tool T can be performed without using a power source, the structure of the moving mechanism 3 can be simplified and the size of the machining device 1 can be made compact. Moreover, the power source necessary for the machining device 1 can be only the motor 2A of the rotation mechanism 2. For this reason, the machining device 1 can be configured as a hand tool easy to carry.

  In the illustrated example, the moving mechanism 3 can linearly move the tool T in two directions X and Y respectively perpendicular to the tool axial direction Tax and orthogonal to each other without using a power source such as a motor. Is configured as. In addition, in the illustrated example, the moving mechanism 3 is configured to be able to position the tool T in the tool axial direction Tax before the rotational operation of the tool T.

  More specifically, the illustrated moving mechanism 3 includes the base 6, the first linear motion guide 7, the first movable portion 8, the second linear motion guide 9, the second movable portion 10, and the feed screw 11. , A feed screw 12, a handle 14, and a tool axis slide mechanism 15.

  The base 6 is a main body for mounting the mechanical component parts constituting the moving mechanism 3. In the illustrated example, a plate-like base 6 is provided as a component of the moving mechanism 3. The first linear motion guide 7 is fixed to the base 6.

  The first linear motion guide 7 is a guide for linearly moving the first movable portion 8 in a first direction X perpendicular to the tool axial direction Tax. Therefore, the first movable portion 8 is slidably combined with the first linear guide 7 in the first linear guide 7. The second linear motion guide 9 is fixed to the first movable portion 8. The second linear motion guide 9 is a guide for linearly moving the second movable portion 10 in a second direction Y perpendicular to the tool axial direction Tax. Therefore, the second movable portion 10 is slidably combined with the second linear guide 9 in the second linear guide 9. As the first linear motion guide 7 and the second linear motion guide 9, for example, commercially available linear guides can be used.

  Further, two feed screw supports 13 are fixed to the position of the base 6 sandwiching the first linear motion guide 7. The feed screw 11 is supported by the two feed screw supports 13. Therefore, the longitudinal direction of the feed screw 11 is the first direction X which is the moving direction of the first movable portion 8. A trapezoidal screw is typically used as the feed screw 11.

  On the other hand, the feed nut 12 is fixed to the first movable portion 8. The feed nut 12 is tightened to the feed screw 11. The handle 14 is connected to one end of the feed screw 11. Accordingly, when the operator turns the handle 14, the feed screw 11 is rotated, and the first movable portion 8 along the first linear guide 7 with the feed nut 12 clamped to the feed screw 11 in the first direction X Can slide on.

  On the other hand, the second movable portion 10 can freely move in the second direction Y along the second linear movement guide 9. In the illustrated example, the first direction X is the horizontal direction, and the second direction Y is the vertical direction. For this reason, the second linear guide 9 and the dropout stopper 10A projecting toward the first movable portion 8 are provided above the second movable portion 10 so that the second movable portion 10 does not fall. . Then, the falling-off stopper 10A of the second movable portion 10 comes into contact with the upper end of the first movable portion 8, whereby the second movable portion 10 is prevented from falling. Thereby, the second movable portion 10 can be freely slid in the vertical direction with the state in which the detachment stopper 10A contacts the upper end of the first movable portion 8 as the lowermost position of the movable range of the second movable portion 10 it can.

  When the second direction Y, which is the moving direction of the second movable portion 10, is not limited to the vertical direction, the two movable stoppers 10A are provided on the second movable portion 10 to form the second movable portion 10 The movable range of the lens may be restricted.

  The rotation mechanism 2 holding the tool T is coupled to the second movable unit 10 that freely moves in the second direction Y by inertia. Therefore, while rotating the handle 14 manually, the rotation mechanism 2 can be moved in the first direction X while the rotation mechanism 2 can be freely moved in the second direction Y. That is, while the illustrated moving mechanism 3 manually moves the tool T and the rotating mechanism 2 in the first direction X perpendicular to the tool axial direction Tax, the tool T and the rotating mechanism 2 in the tool axial direction Tax It can be freely moved in the second direction Y perpendicular to the direction.

  On the other hand, the tool axis slide mechanism 15 for sliding the tool T in the tool axis direction Tax can be provided, for example, in the rotation mechanism 2. Of course, another movable part for moving the first movable part 8 or the second movable part 10 in the tool axis direction Tax may be provided as the tool axis slide mechanism 15 in the machining device 1.

  FIG. 5 is a cross-sectional view at position AA showing an example of the structure of the rotation mechanism 2 shown in FIG.

  As illustrated in FIG. 5, the rotation mechanism 2 has a holder 2 </ b> B that rotates the tool T by the drive of the motor 2 </ b> A. The rotary mechanism 2 can be provided with a cylindrical slider 15A and a clamping clamp 15B as the tool axis slide mechanism 15. The cylindrical slider 15A has a cylindrical structure, and is coaxially fixed to the casing of the motor 2A with the tool T so that the tool T held by the holder 2B is inside.

  On the other hand, the clamping clamp 15 B is fixed to the second movable portion 10. The clamping clamp 15B has a tubular structure provided with a slit, and is provided with a female screw straddling the slit. The longitudinal direction of the slit is axial, and the male screw connected to the tip of the clamp lever 15C is tightened to the female screw straddling the slit. For this reason, when the male screw is rotated by the rotation of the clamp lever 15C, the width of the slit is narrowed, and the inner diameter of the clamp 15B can be reduced.

  A clamping clamp 15B having such a structure is clamped to the outside of the cylindrical slider 15A. Accordingly, when the clamp 15B is loosened by the rotation of the clamp lever 15C, the cylindrical slider 15A can be axially slid relative to the clamp 15B. On the other hand, when the clamp 15B is tightened by the rotation of the clamp lever 15C, the clamp 15B can be fixed to the cylindrical slider 15A.

  Therefore, when the clamping clamp 15B is loosened, the relative position in the tool axial direction Tax between the motor 2A, the holder 2B, the tool T and the cylindrical slider 15A, and the clamping clamp 15B and the second movable portion 10 can be adjusted. . Then, the positions of the motor 2A, the holder 2B, the tool T, and the cylindrical slider 15A in the tool axial direction Tax can be fixed by tightening the tightening clamp 15B. Thereby, positioning of the tool T in the tool axial direction Tax can be performed.

  The guide member 4 is a component for guiding the movement of the tool T along the shape of the workpiece W after processing. As described above, since the cutting surface or the finishing surface is formed in the tool axial direction Tax of the tool T, the guide member 4 can guide the movement of the tool T in the direction perpendicular to at least the tool axial direction Tax. Configured

  On the other hand, the rotating mechanism 2 can be provided with a non-rotating portion 2C that moves with the tool T but does not rotate with the tool T. The guide member 4 can be provided with a guide surface for sliding the non-rotating portion 2C of the rotation mechanism 2 so that the tool T moves in the moving direction perpendicular to the tool axis direction Tax. Then, by sliding the non-rotation portion 2C of the rotation mechanism 2 while bringing the non-rotation portion 2C of the rotation mechanism 2 into contact with or close to the guide surface of the guide member 4, the tool T can be slid along the guide surface of the guide member 4 together with the non-rotation portion 2C. it can.

  In the illustrated example, a non-rotational portion 2C having a structure in which a cylindrical protrusion is coaxially provided on a disk-shaped member having a through hole at its center is integrated with the clamp clamp 15B of the rotation mechanism 2. And the tool T is inserted in the through-hole which penetrates a disk-shaped member and cylindrical protrusion. In other words, the rotating mechanism 2 is configured to hold the shank side of the tool T with the holder 2B in a state where the cutting edge side of the tool T protrudes from the non-rotating portion 2C. Therefore, the non-rotating portion 2C can be moved together with the tool T in a moving direction perpendicular to the tool axial direction Tax without rotating the non-rotating portion 2C.

  On the other hand, the guide member 4 can be configured by, for example, a plate 4B provided with a slit 4A penetrating therethrough. Then, the width of the slit 4A and the diameter of the cylindrical protrusion of the non-rotating portion 2C may be determined so that the cylindrical protrusion of the non-rotating portion 2C fits into the slit 4A of the plate 4B with a tolerance greater than the clearance fit. it can. Then, the non-rotational portion 2C can be slid in the longitudinal direction of the slit 4A in a state where the cylindrical protrusion of the non-rotational portion 2C is fitted into the slit 4A of the plate 4B. In this case, the movable direction of the non-rotating portion 2C is restricted in the longitudinal direction of the slit 4A. Therefore, the non-rotating portion 2C of the rotating mechanism 2 can be slid only in one direction by the moving mechanism 3.

  Therefore, it can be said that the non-rotating portion 2C of the rotating mechanism 2 constitutes a part of a guide mechanism that guides the moving direction of the tool T. Specifically, the guide member 4 constituted by the plate 4B provided with the slits 4A functions as a female of the guide mechanism, and the non-rotational portion 2C of the rotation mechanism 2 functions as a male of the guide mechanism to be fitted into the guide member 4 .

  The plate 4B is not limited to the slit 4A having a straight center line, but may be provided with a slit 4A having a non-straight center line like a broken line or a curve. Therefore, the non-rotating portion 2C of the rotating mechanism 2 can be slid linearly or non-linearly by the guide member 4.

  The center line of the slit 4A is a locus of the center axis of the tool T. Therefore, the shape of the slit 4A may be determined such that the position offset from the contour after machining of the workpiece W becomes the center line so that the cutting surface of the tool T moves along the shape after machining of the workpiece W it can. In this case, the offset amount between the processed outline of the workpiece W and the center line of the slit 4A may be the radius of the tool T.

  In the illustrated example, the machining device 1 is attached to the work W in order to cut the tab W2 provided on the panel W1. Moreover, the external shape of the part of panel W1 after cutting of tab W2 is linear shape. Accordingly, the machining device 1 is provided with a plate 4B provided with a linear slit 4A having a length that can cover the cut length of the tab W2.

  However, depending on the work W, the cut length of the tab W2 may be different, or the outer shape of the work W may have a curved shape. Alternatively, even if the outer shape of the workpiece W is linear, it may tilt relative to the drive shaft of the moving mechanism 3. Further, as described above, not only cutting of the tab W2 but also linear or non-linear finishing may be performed by the machining device 1.

  Therefore, the guide member 4 can be replaced so as to obtain versatility of the machining device 1. As a specific example, a first guide member that guides the linear movement of the tool T in a direction perpendicular to the tool axial direction Tax, and a curved movement of the tool T in a direction perpendicular to the tool axial direction Tax The second guide member may be provided exchangeably in the machining device 1.

  In this manner, the moving mechanism 3 can move the tool T along the guide member 4 in a direction perpendicular to at least the tool axis direction Tax. For example, when the guide direction of the guide member 4 is the first direction X, the tool T and the rotation mechanism 2 can be slid in the first direction X following the guide member 4 by turning the handle 14.

  On the other hand, if the tool T and the rotation mechanism 2 can be moved in two directions perpendicular to the tool axis direction Tax as shown in the drawing, the guide direction of the guide member 4 is different from the first direction X. Even if the tool T and the rotating mechanism 2 are manually moved in the first direction X perpendicular to the tool axial direction Tax by turning the handle 14, the non-rotating portion 2C along the contact surface of the guide member 4 The tool T can be freely moved in the second direction Y perpendicular to the tool axial direction Tax in accordance with the slide of.

  For this reason, the tool T can be moved linearly or non-linearly following the shape of the contact surface of the guide member 4 having an arbitrary shape. Thereby, it is possible to cut or finish the work W into a free shape.

  In the illustrated example, by providing the slit 4A in the guide member 4, two guide surfaces for suppressing the movement of the non-rotational portion 2C in the width direction of the slit 4A are formed in the guide member 4 The guide member 4 may be formed with one guide surface. For example, the guide member 4 may be formed of a plate-like member, and the outer shape of the plate-like member may be used as a guide surface. Also in this case, for example, the non-rotational portion 2C can be moved along the guide surface while being in contact with the guide surface of the guide member 4 using gravity.

  On the other hand, the position and structure of the non-rotating portion 2C are also arbitrary. For example, the non-rotating portion 2C moving in contact with or in close proximity to the guide surface of the guide member 4 may be a rectangular or oblong protrusion having a flat surface parallel to the guide surface instead of the cylindrical protrusion. Alternatively, the part such as a protrusion may be provided at a desired position without penetrating the tool T through the part such as a protrusion of the non-rotating portion 2C that moves in contact with or in proximity to the guide surface of the guide member 4. That is, at any position of the non-rotating portion 2C, it is possible to form one or more flat surfaces or curved surfaces in contact with or in proximity to one or more guide surfaces of the guide member 4. Then, at least a part of the non-rotating portion 2 </ b> C of the rotating mechanism 2 can be guided by the guide surface of the guide member 4.

  In addition, as shown in the figure, if the non-rotating portion 2C is provided with a disc-like portion, the disc-like portion can be brought into contact with or close to the surface of the plate 4B during processing. Therefore, the movement of the non-rotating portion 2C in the tool axis direction Tax can also be restricted by the disk-shaped portion of the non-rotating portion 2C and the plate 4B. Therefore, the projection length of the tool T from the plate 4B to the work W can be made equal to or less than a predetermined length.

  In addition, if the cylindrical protrusion of the non-rotating portion 2C is moved along the slit 4A of the plate 4B while bringing the disc-shaped portion of the non-rotating portion 2C into contact with the surface of the plate 4B, the work W from the plate 4B It is possible to slide the non-rotating portion 2C while keeping the projection length of the tool T to the side constant. For this reason, the movement of the tool T in the tool axial direction Tax can also be guided by the guide member 4.

  When the guide member 4 for guiding the non-rotating portion 2C can be replaced, it is appropriate that the operator can easily disassemble and assemble the guide member 4. Therefore, in the illustrated example, the guide member 4 is configured to be easily attached to and detached from the base 6 with a bolt.

  Further, it is preferable to provide the pinching member 16 for pinching the workpiece W with the guide member 4 from the viewpoint of clamping the workpiece W more reliably. In the example shown, the pinching member 16 is associated with the guide member 4 by means of the coupling member 17. Specifically, the C-shaped connecting member 17 is fixed to the upper end side of the guide member 4 by a tightening bolt, and the holding member 16 is sandwiched together with the work W by the connecting member 17.

  Further, the pinching member 16 is pressed from the back side of the work W toward the guide member 4 by the disc-shaped clamp 18. The disc-shaped clamp 18 can be configured by attaching a push screw 18B to the C-shaped frame 18A and providing a plate-like disc 18C at the tip of the push screw 18B. Both ends of the C-shaped frame 18A are fixed to both ends of the guide member 4 by tightening bolts. Then, when the push screw 18B is turned, the plate-like disc 18C is pressed against the sandwiching member 16. Thereby, at the time of machining, the workpiece W can be clamped and clamped by the clamping member 16 arranged on the tip side of the tool T and the guide member 4 arranged on the shank side of the tool T. Conversely, after machining is completed, the pinching member 16, the coupling member 17 and the disc clamp 18 can be easily removed together with the guide member 4.

  FIG. 6 is a perspective view showing an example of the shape of the pinching member 16 in a state in which the disk-shaped clamp 18 shown in FIG. 4 is removed.

  If the application of the machining device 1 is cutting of a tab W2 or the like, the cutting will generate fragments. Therefore, as shown in FIG. 6, the first sandwiching member 16A for sandwiching the cut-off side such as the tab W2 with the guide member 4 and the product side of the work W such as the panel W1 as the guide 4 It is effective to provide the second sandwiching member 16B for sandwiching between and on the back side of the work W from the viewpoint of reliably clamping the work W.

  When the workpiece W is cut by linear processing like the tab W2, as shown in the drawing, the first pinching member 16A having a linear outer shape and the second pinching member 16B have the diameter of the tool T. It may be disposed apart by the above distance. On the other hand, when the workpiece W is cut by non-linear processing, the first pinching member having a shape conforming to the shape of the workpiece W after cutting and the second pinching member are not less than the diameter of the tool T It may be arranged apart by a distance. Further, if the finishing process of the work W is the purpose, the work W can be sandwiched between the single sandwiching member 16 and the guide member 4.

  In particular, the shape of the single sandwiching member 16 for sandwiching the workpiece W with the guide member 4 or the second sandwiching member 16B for sandwiching the product side of the workpiece W with the guide member 4 is the same as the workpiece W If the shape conforms to the shape after machining, generation of burrs associated with cutting can be prevented. As a result, the finishing accuracy of the cut or finished surface can be improved.

  In the example shown in FIG. 6, a hole for inserting a positioning pin into the second sandwiching member 16B so that the outer shape of the second sandwiching member 16B can be accurately matched with the shape of the workpiece W after processing; Holes are provided for bolting. Therefore, the second sandwiching member 16B can be pressed against the work W in a state where the second sandwiching member 16B is fixed to the disk 18C of the disk type clamp 18 at the correct position by the positioning pin and the bolt.

  The machining device 1 including the rotation mechanism 2, the guide member 4, the movement mechanism 3 and the sandwiching member 16 as described above can be attached to the work W by the attachment 5. In the illustrated example, the base 6 is provided with an internal thread so that the C-shaped clamp can be attached to the internal thread of the base 6 as the attachment 5. Of course, any clamp such as a giant vise may be used as the mounting tool 5.

(Operation and action)
Next, a machining method for producing a machined product using the machining device 1 will be described.

  First, the machining device 1 is attached by the attachment 5 at a predetermined position of the workpiece W to be processed. Specifically, the machining device 1 is fixed to the work W by the mounting fixture 5 such as a C-shaped clamp so that the processing position of the work W is within the range of the stroke of the tool T held by the rotation mechanism 2. For example, in the case where the work W is a panel W1 which is one of aircraft parts, the machining device 1 is mounted in alignment with the processing position of the panel W1 by a mounting tool 5 such as a C-shaped clamp as shown.

  The material of the work W is not limited to metal, and may be a composite material such as glass fiber reinforced plastic (GFRP) or carbon fiber reinforced plastic (CFRP). Further, the processing purpose of the work W can be various purposes such as grooving of the work W as well as cutting of the tab W2 and finishing of the outer shape of the panel W1.

  Generally, in machining of aircraft parts, outline processing is performed by providing an excess thickness of about 0.5 mm so that no gap occurs when assembling the aircraft parts. Therefore, when assembling the aircraft parts, it is necessary to finish the outer shape of the aircraft parts to be assembled. This applies not only to metal parts but also to composite parts. Therefore, it is possible to use the machining device 1 to perform finish processing to remove excess thickness of aircraft parts. Also, the tab W2 can be cut in combination with the finishing process of the outer shape. Alternatively, the tab W2 can be cut independently of the finishing process of the outer shape.

  For this reason, the guide member 4 corresponding to the application of the machining device 1 is assembled to the machining device 1. That is, when the non-rotating portion 2C of the rotating mechanism 2 is moved along the guide surface of the guide member 4, the guide member 4 is the processing position of the work W such that the movement path of the tool T becomes the processing path of the work W Is addressed to For example, if the contour finish of the panel W1 is to be processed, the guide member 4 is positioned so that the trajectory of the cutting surface of the tool T follows the contour of the panel W1 after the contour finish. In addition, the non-rotation portion 2C of the rotation mechanism 2 is set to the initial position.

  Furthermore, as in the case of cutting the tab W2, when a fragment is produced by cutting the work W, the pinching member 16 is connected to the guide member 4 by the connecting member 17, and the work W is held by the guide member 4 and the pinching member 16 Sandwiched between. Therefore, the pinching member 16 is also prepared in accordance with the shape of the workpiece W after processing, and positioned at an appropriate position in accordance with the shape of the workpiece W after processing.

  Specifically, when the workpiece T is machined by moving the tool T, the pinching member 16 is positioned so that at least the tool T does not interfere with the pinching member 16. More preferably, the pinching member 16 is positioned such that the surface through which the cutting surface of the tool T passes is substantially the end face of the pinching member 16. In other words, the pinching member 16 is positioned such that the contour of the workpiece W after machining and the contour of the pinching member 16 substantially match. Thereby, generation | occurrence | production of the burr | flash at the time of machining can be suppressed or reduced.

  The guide member 4 may be assembled in advance to the machining device 1 before attaching the machining device 1 to the work W, or after temporarily fixing the machining device 1 to the work W, the guide member 4 may be machined 1 The position of the machining apparatus 1 may be finely adjusted so that the relative position of the guide member 4 to the work W is an appropriate position.

  Therefore, when attaching the pinching member 16 to the machining device 1, the pinching member 16 can be connected to the guide member 4 by the connecting member 17 after the guide member 4 is positioned in accordance with the work W. Alternatively, in accordance with the shape of the cut portion of the work W such as the tab W2, the pinching member 16 is connected by the guide member 4 and the connecting member 17 and assembled in advance, and machining is performed in a state where the pinching member 16 and the guide member 4 are assembled. It may be attached to the device 1.

  When the pinching member 16 is disposed on the back of the work W, the disc clamp 18 is fixed to the guide member 4 and the disc clamp 18 presses the pinching member 16 against the back of the work W. As a result, the cut portion such as the tab W2 can be firmly held by the holding member 16 and the guide member 4 so that no gap is generated.

  When the attachment of the guide member 4 and the pinching member 16 in the required case is completed, the non-rotating portion 2C of the rotation mechanism 2 in the initial position contacts or approaches the initial position of the guide surface of the guide member 4. Further, the tool T protrudes from the non-rotating portion 2C toward the workpiece W, and the position of the tool T becomes the initial position of the processing path. Thereby, machining of the workpiece W can be started.

  Therefore, the motor 2A of the rotation mechanism 2 is switched to the ON state and driven. For this reason, the tool T rotates. Next, the tool T is moved along with the rotation mechanism 2 along the guide member 4 by the drive of the movement mechanism 3. Thereby, machining of the workpiece W can be performed.

  For example, as illustrated in the moving mechanism 3, the first movable portion 8 manually moved in the first direction X and the second movable portion 10 freely moved in the second direction Y by the rotation of the handle 14. If provided, the operator rotates the handle 14. Then, the first movable portion 8 slides in the first direction X along the first linear motion guide 7.

  On the other hand, the non-rotating portion 2 </ b> C of the rotating mechanism 2 moves along the guide member 4. As a specific example, when the guide member 4 is the plate 4B provided with the slit 4A, a portion such as a cylindrical protrusion of the non-rotational portion 2C inserted in the slit 4A moves in the longitudinal direction of the slit 4A. Therefore, when the moving direction of the non-rotating portion 2C is different from the first direction X which is the drive shaft of the first movable portion 8, the non-rotating portion 2C is pressed by the guide member 4 in the second direction Y. As a result, the second movable unit 10 moves in the second direction Y due to inertia. Therefore, the tool T moves along a path corresponding to the shape of the guide member 4.

  When the rotation mechanism 2 and the tool T are moved along the guide member 4, the workpiece W can be processed along the shape of the guide member 4. The machining of the work W is continued until the non-rotating portion 2C of the rotating mechanism 2 reaches the end of the guide member 4 or the operator stops the rotation of the handle 14.

  For example, if the purpose of machining is cutting of the tab W2, the movement of the tool T is stopped at least at a position where the tool T has crossed the tab W2. Thereby, the tab W2 can be cut. In this case, the tab W2 after cutting is held in a state of being sandwiched between the guide member 4 and the sandwiching member 16. In addition, when the purpose of machining is finishing of the outer shape, the movement of the tool T is stopped at least when the tool T passes through the finishing area.

  In this manner, the machined device 1 can be used to manufacture a machined product made of metal or composite material. For example, a machined product can be manufactured with at least one of cutting of the tab W2 and finishing to remove excess thickness. Further, if the contour of the workpiece W is a curve, a machined product can be manufactured by moving the tool T in a curvilinear manner.

  Furthermore, when the moving mechanism 3 can slide the tool T in the tool axial direction Tax, the cutting amount in the tool axial direction Tax can be reduced and machining can be performed a plurality of times. Specifically, a machined product can be manufactured by processing in which the tool T is moved in the direction perpendicular to the tool axial direction Tax a plurality of times while changing the position of the tool T in the tool axial direction Tax.

  For example, in the case of cutting the workpiece W such as the tab W2, the groove processing is repeated plural times while changing the position of the tool T in the tool axial direction Tax. On the other hand, in the case of finishing the outer shape of the work W, the process of removing the excess thickness while repeating the position of the tool T in the tool axis direction Tax is repeated multiple times.

  Such step processing is effective when the thickness of the work W is thick, when the work W is in a block shape, or when the processed portion of the work W is a side surface such as a flange. That is, since the cutting amount of the tool T can be set small by the step processing, the accuracy of the finished surface can be improved by the reduction of the cutting resistance.

  In addition, in the case where it is important to improve the accuracy of the finished surface in particular, the finish processing may be performed after roughing processing using the machining device 1. Thereby, in the side process of a flange, the process of the workpiece | work W with thick plate thickness, etc., a finishing surface can be made favorable. As a specific example, the outer shape finishing, cutting, or trimming of the work W can be performed while leaving an excess thickness of about 0.1 mm to 0.2 mm, and then the outer shape finishing of the work W can be performed. Even in such a case, rough processing may be performed by step processing. Furthermore, finishing may also be performed by step processing.

  In the case where the finishing is performed after the roughing by the machining device 1, it is necessary to offset the path of the tool T by the thickness of the excess thickness. Therefore, the first guide member 4 for roughing and the second guide member 4 for finishing may be prepared and exchanged. Alternatively, a shim may be attached to and detached from the guide member 4 to offset the position by the thickness of the extra thickness. As another method, the position of the guide member 4 or the position of the machining device 1 itself may be finely adjusted by an adjuster or shim.

  The machining apparatus 1 as described above makes the moving mechanism 3 for moving the tool T together with the rotating mechanism 2 for rotating the tool T and the rotating mechanism 2 attachable to and detachable from the work W by means of the mounting tool 5. It is possible to guide the direction of movement of

(effect)
For this reason, according to the machining device 1 and the machining method, the workpiece W can be easily machined without using large-scale equipment such as a machine tool. For example, cutting of the tab W2 and finishing of the outer shape can be performed easily and in a short time without depending on the manual work of the operator.

  Moreover, since the moving direction of the tool T can be guided by the guide member 4, variation in the quality of the machined product can be reduced as compared with the case where the operator performs a manual operation. In addition, the accuracy of the finished surface of the machined product can be improved. As a result, it is possible to shorten the production time of the machined product by omitting the finishing operation of the machined product by manual work.

  In addition, replacement of the guide member 4 enables processing of various shapes. For this reason, it is possible to provide a machining device 1 that is handheld but versatile.

  Although the specific embodiments have been described above, the described embodiments are merely examples and do not limit the scope of the invention. The novel methods and apparatus described herein may be embodied in various other ways. Also, various omissions, substitutions and changes in the form of the methods and apparatus described herein may be made without departing from the spirit of the invention. The appended claims and their equivalents are intended to cover such different forms and modifications as fall within the scope and spirit of the invention.

  For example, in the embodiment described above, a cutter such as an end mill or a drill having a cutting edge formed on a shank has been exemplified as the tool T, but depending on the application of the machining device 1 a grinding wheel or a deburring brush as the tool T Any tool having a cutting portion on its shank can be used. For this reason, for example, if a grindstone is used as the tool T, it is possible to perform surface finishing or contour finishing of a flat surface or a curved surface.

  DESCRIPTION OF SYMBOLS 1 ... Machining apparatus, 2 ... rotation mechanism, 2A ... motor, 2B ... holder, 2C ... non-rotation part, 3 ... moving mechanism, 4 ... guide member, 4A ... Slit, 4B ... plate, 5 ... mounting fixture, 6 ... base, 7 ... first linear guide, 8 ... first movable part, 9 ... ninth 2 linear motion guides, 10: second movable portion, 10A: dropout stopper, 11: feed screw, 12: feed nut, 13: feed screw support, 14: Handle, 15: Tool axis sliding mechanism, 15A: Cylindrical slider, 15B: Clamping clamp, 15C: Clamping lever, 16: Clamping member, 16A: First clamping member, 16B ... 2nd pinching member, 17 ... connection member, 18 ... disk type clamp, 18A ... C type frame, 18B ... push screw, 18C ... disk, W ... work , W1 ... panel, W2 ... tab, T ... tool

Claims (10)

A rotation mechanism for holding and rotating the shank of a tool having a shank and a cutting portion;
A guide member for guiding the movement of the tool in the direction perpendicular to the tool axis direction along the shape after machining of the workpiece, the non-rotating portion of the rotation mechanism moving with the tool A guide member having a guide surface that slides linearly or non-linearly in only one direction ;
The tool is manually operated in the first direction perpendicular to the tool axis direction together with the non-rotating portion so that the non-rotating portion slides linearly or non-linearly along the guide surface of the guide member. A moving mechanism for freely moving the tool in a second direction perpendicular to the tool axis direction without using a power source while moving along the guide surface of the non-rotating portion, ,
An attachment for attaching the rotation mechanism, the guide member, and the movement mechanism to the object to be processed;
A machining device having The moving mechanism, the machining apparatus of the tool a further claim 1 configured to be able to move in the tool axis direction. A sandwiching member for sandwiching the product side of the object to be machined with the guide member on the tip end side of the tool, and generation of burrs accompanying cutting of the article to be machined by movement of the tool is prevented the workpieces of the post-process machining apparatus according to claim 1 or 2, wherein further comprising a gripping members having a contour matching the contour as. The machining apparatus according to any one of claims 1 to 3, further comprising a pinching member for pinching a fragment side to be cut from the workpiece at the tip end of the tool with the guide member. A first guide member for guiding the linear movement of the tool in a direction perpendicular to the tool axis direction; and a second guide member for guiding a curvilinear movement of the tool in the direction perpendicular to the tool axis direction The machining device according to any one of claims 1 to 4 , which is configured to be exchangeable with the guide member. A machining method for producing a machined product using the machining device according to any one of claims 1 to 5 . The machining method according to claim 6, wherein a machined product composed of a composite material is manufactured. The machining method according to claim 6 or 7 , wherein the machined product is manufactured by moving the tool in a curvilinear manner. A machined article is manufactured by a process of moving the tool a plurality of times in the direction perpendicular to the tool axis direction while changing the position of the tool in the tool axis direction using the machining apparatus according to claim 2 Machining method. The machining method according to any one of claims 6 to 9 , wherein the machined product is manufactured with at least one of cutting of a tab using the machining device and finishing for removing excess thickness.

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