JP2006142454A - Grinding wheel forming device for surface grinding machine and dressing method for grinding wheel using the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To precisely and uniformly dress a grinding wheel for a surface grinding machine with a small type cylindrical rotary dresser in a short period of time. <P>SOLUTION: In the grinding wheel forming device 40 for the surface grinding machine 1, the cylindrical rotary dresser 41 is mounted on the one end of a reciprocatingly movable worktable 4 in the right and left direction so that a dresser rotating shaft 42 is mounted in the fore-and-aft direction and parallel to the surface of the worktable. A grinding wheel head 10 disposed on the upper position of the worktable is movably provided in the fore-and-aft direction and vertical direction relative to the worktable, and the grinding wheel 3 is provided on the grinding wheel head around the axis of the grinding wheel spindle 11 in the fore-and-aft direction. The outer peripheral surface of the cylindrical rotary dresser 41 is relatively dressed by copying the use surface of the grinding wheel head 3 by combining the right and left reciprocating movement of the cylindrical rotary dresser 41, and the fore-and-aft movement and the vertical movement of the grinding wheel 3. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a cylindrical rotary dresser for forming (dressing) a grinding wheel of a surface grinding machine for stroke grinding a groove in a super steel punch member or a connector member, and a grinding wheel of a surface grinding apparatus using the same. It is related with the method of dressing in a short time.

  The method of forming a grinding wheel of a surface grinding machine using a diamond single stone dressing tool shortens the life of the dressing tool and also increases the time required for forming the grindstone. Therefore, a rotary dresser is used instead. There are many opportunities to be used.

  A grinding wheel forming apparatus that forms a grinding wheel using a rotary dresser is roughly divided from the positional relationship between the rotary axis of the rotary dresser and the spindle axis of the grinding wheel, and there are two types of grinding wheel forming apparatuses. And dressing methods have been proposed.

  (A). As shown in FIG. 5a, a cylindrical rotary dresser 41 mounted on a work table 4 that can reciprocate in the left-right direction (X-axis direction) and the front-rear direction (Z-axis direction) is used. A grindstone rotatably mounted on a grindstone shaft of a surface grinding machine 1 mounted on a tool table 7 that can reciprocate in the front-rear direction (Z-axis direction) so as to be movable up and down (Y-axis direction). A grindstone forming apparatus for dressing a car has been proposed, and when dressing is performed, the rotary dresser 41 is rotated and the rotary dresser 41 and the grindstone wheel 3 are relatively moved in the vertical direction. The usage surface of the grinding wheel 3 is dressed in a predetermined shape on the outer peripheral surface of the rotary dresser 41 by changing the axis of the rotary dresser 41 so as to follow the usage surface of the grinding wheel 3. At this time, the dressing of the grindstone is performed while moving the rotary dresser 41 and the grinding wheel 3 in the vertical direction, thereby preventing uneven wear of the rotary dresser 41. In this grindstone forming apparatus 40, the dresser shaft 42 of the rotary dresser 41 is installed in the vertical direction, and the spindle shaft 11 of the grinding wheel 3 is installed perpendicular to the horizontal direction (for example, Patent Document 1 and Patent Document 2). And Patent Document 3).

(I). As shown in FIG. 5b, the dresser shaft of the rotary dresser 41 mounted on the work table 4 reciprocally movable in the left-right direction (X-axis direction) is set in the horizontal direction, and the front-rear direction (Z-axis direction). ) And a grinding wheel molding apparatus 40 in which the spindle shaft of the profile grinding wheel 3 movable in the vertical direction (Y-axis direction) is horizontally installed so as to be parallel to the rotational axis of the rotary dresser, ) After moving the rotary dresser just below the grinding wheel 3 by moving the work table 4, b) lowering the rotating grinding wheel to make a desired amount of cut in the radial direction of the grinding wheel. A step, c) a step of raising the grinding wheel and moving it away from the rotary dresser, d) a step of moving the grinding wheel by a predetermined pitch in the front-rear direction, e) the step b), c) step and d) step. Repeat the grinding wheel's outer periphery to the desired shape To Lessing (e.g., Patent Document 4, Patent Document 5, Patent Document 6 and Patent Document 7).
JP-A-7-164314 (see page 2-4, FIG. 1) Japanese Examined Patent Publication No. 6-61700 (see page 2-4, FIG. 1) Japanese Patent Laid-Open No. 9-11130 (see page 2-4, FIG. 1, FIG. 5, FIG. 6) Japanese Patent Laid-Open No. 9-29628 (see page 3-5, FIG. 1 and FIG. 7) Japanese Patent Laid-Open No. 50-74883 (see page 2, FIG. 2) JP-A-2-24057 (see page 2-4, FIG. 1 and FIG. 7) Japanese Patent Laid-Open No. 9-29628 (see page 3-5, FIG. 1 and FIG. 7)

  The grindstone forming apparatus mounted on the work table with the dresser rotation axis orthogonal to the horizontal grindstone spindle shaft described in Patent Document 1 to Patent Document 3, the grinding center point of the grinding wheel and the grinding wheel The position coordinates of the surface are detected, and the grinding wheel is brought into contact with the outer peripheral surface of the cylindrical rotary dresser to carry out the copying process, but the dresser shaft is placed with the cross-section disk-shaped plane of the roll dresser 41 of the grinding wheel forming device facing upward. Since it is placed upright on the work table, it tends to be an obstacle to the grinding work, and the footprint area of the surface grinding machine is increased.

  The spindle shaft of the profile grinding wheel 3 described in Patent Document 4 to Patent Document 7 is installed in the horizontal direction so as to be parallel to the rotational axis of the rotary dresser, and the outer peripheral surface follows the grinding wheel. In the dressing method in which the grinding wheel is brought into contact with the outer peripheral surface of the rotary dresser by using the rotary dresser 41 having a profile, the grinding wheel forming apparatus is installed on one end side of the work table. As compared with the grindstone forming apparatus described in Patent Documents 1 to 3, there is an advantage that does not become an obstacle to work during grinding. In the present invention, the grindstone forming apparatus can be further reduced in size as compared with these conventional grindstone forming apparatuses, and the hit print can be narrowed and the dressing time is shortened without interfering with the work grinding process. An object of the present invention is to provide a grindstone forming apparatus for a surface grinder capable of performing the above.

  According to the first aspect of the present invention, a cylindrical rotary dresser is provided on one end of a worktable that can be reciprocated in the left-right direction of a surface grinding machine, and the work rotation is such that the dresser rotation axis is in the front-rear direction. A grinding wheel mounted so as to be parallel to the bull surface and rotatably supported by the grinding wheel spindle shaft of the grinding wheel head of the surface grinder is positioned above the working table with respect to the working table. The present invention provides a grinding wheel forming apparatus for a surface grinder provided to be movable in the front-rear direction and in the vertical direction.

  According to a second aspect of the present invention, the grinding wheel forming apparatus according to the first aspect is used, and the grinding wheel of the surface grinding machine is lowered so that the lower end of the grinding wheel is below the top of the cylindrical rotary dresser. After rotating the work table, the cutting wheel of the rotating grinding wheel is started by the rotating cylindrical rotary dresser by reciprocating left and right and rotating while the height is positioned downward by the dressing allowance. The grinding wheel is moved to the rear side or the front side while the grinding wheel is raised following the circular arc shape of the cylindrical rotary dresser, and the grinding wheel shape is copied, and the center of the thickness width of the grinding wheel is obtained. When the vertical line passing through the center of the cylindrical rotary dresser reaches the position where it passes through the dresser rotation axis, the work table continues to reciprocate left and right while lowering the height of the grinding wheel by the dressing allowance. Although it is located in While the grinding wheel is lowered following the circular arc shape of the cylindrical rotary dresser, the grinding wheel is moved rearward or forward to form the grinding wheel by the cylindrical rotary dresser following the grinding wheel shape. The present invention provides a grinding wheel dressing method for a surface grinding machine, characterized in that the working surface of the grinding wheel is dressed into a predetermined shape on the outer peripheral surface of a cylindrical rotary dresser by processing.

  In the dressing method, the axis of the cylindrical rotary dresser is relatively changed to follow the usage surface of the grinding wheel, and the usage surface of the grinding wheel is dressed into a predetermined shape on the outer peripheral surface of the rotary dresser. be able to. The grinding wheel forming apparatus according to the present invention moves the rotary rotor dresser in the left-right direction while moving the height downward by the dressing allowance following the circular arc shape of the cross section of the cylindrical rotary dresser. The grinding wheel is molded by the rotary dresser by raising or lowering the rotating grinding wheel following the circular arc shape of the rotary dresser, so that the grinding wheel molding apparatus becomes compact and the dressing time is reduced. Although it is shortened compared with the dressing method described in the said patent document group, it does not become long.

Hereinafter, the present invention will be described in more detail with reference to the drawings.
FIG. 1 is a perspective view of a surface grinder equipped with a grindstone forming apparatus, FIG. 2 is a side view of a portion of the surface grinder, FIG. 3 is a front view of the grindstone forming apparatus, and FIG. It is a figure which shows the dressing process of a grinding wheel, and shows the motion of the grinding wheel with respect to the cylindrical rotary dresser seen from the side surface side of the surface grinding machine.

  In the surface grinding machine 1 shown in FIGS. 1 and 2, 2 is a work, 3 is a grinding wheel, 4 is a work table that can reciprocate in the left-right direction (X-axis direction), and 5 is a work table. 6 is an electromagnetic chuck, 7 is a saddle capable of reciprocating in the front-rear direction (Z-axis direction), 8 is an operation panel, 8b is a manual pulse generator button for turning the grindstone up and down, 9 is a column, 10 is a grindstone head, and 11 is a grindstone spindle. A shaft, 12 is a lifting mechanism for moving the grindstone 3 in the vertical direction (Y-axis direction), 13 is a motor, 14 is a screwed body, 15 is a screw shaft, 16 is a screwed body, 17 is a safety protection cover, 18 Is a grinding fluid supply nozzle, 19 is a bed, 20 is a tank, 21 is a filter, 22 is a pump, 23 is a grindstone shaft motor, 24 is a control unit, and 40 is a grindstone forming apparatus.

  The electromagnetic chuck 6 is placed on the work table 4, the work 2 to be processed is placed thereon, the rotating grinding wheel 3 is brought into contact with the work surface, and the work is moved in the left-right direction. The workpiece is ground by the movement and the relative movement of the grinding wheel in the longitudinal direction and the vertical direction. The shaping process (dressing) of the grinding wheel 3 by the cylindrical outer peripheral surface of the cylindrical rotary dresser is performed before, during or after the grinding of the workpiece.

  As shown in FIG. 3, the grindstone forming apparatus 40 has a bearing on the outer periphery of the central portion of a dresser rotary shaft 42 supported at one end by a tailstock (fixed side) 43 and at the other end by a headstock 44 (moving side). A roll-shaped cylindrical rotary dresser 41 is provided. The head stock 44 is urged toward the end of the dresser rotating shaft 42 by a coil spring 45. When the head stock 44 is pushed leftward and the dresser shaft 42 is pulled toward the front, the head stock 44 is rotated about 60 degrees around the head of the tail stock 43. Can be pulled out at an angle.

  A belt 47 is mounted on a pulley 42a pivotally attached to the dresser rotating shaft 42 and a pulley 46a pivotally attached to the motor shaft, and the motor 46 accommodated in the housing 48 is rotated. The driving force is transmitted to the pulley 42a via the belt 47, and the cylindrical rotary dresser 41 is rotated around the dresser shaft center 42b. Reference numeral 49 is a motor power supply, and 50 is a fixing bolt.

  As shown in FIG. 1, the grindstone forming apparatus 40 is fixed to the left end side of the worktable 4 of the surface grinder 1, for example, the left end of the electromagnetic chuck 6 fixed on the worktable 4. Provide. The dresser rotation shaft 42 is installed at a right angle to the grindstone spindle shaft 11, that is, parallel to the horizontal plane so as to face the left-right direction. Therefore, the molding outer peripheral surface of the cylindrical rotary dresser 41 is in a plane orthogonal to the outer peripheral surface of the grinding wheel 3. In order to form the grinding wheel 3 by using the grinding wheel forming apparatus 40, the left and right reciprocating movements of the work table 4 on which the cylindrical rotary dresser 41 is placed and the longitudinal movement of the grinding wheel 3 are performed. And the vertical movement of the rotary dresser 41 are relatively changed so as to follow the usage surface of the grinding wheel 3 so that the usage surface of the grinding wheel 3 has a predetermined shape on the outer peripheral surface of the rotary dresser 41. Dress up. The grinding wheel 3 can rotate about the grinding wheel spindle shaft 11 by receiving the driving force of the motor 23. The grinding wheel 3 is moved by moving the grinding wheel head 10 fixed to the screw 16 mounted on the ball screw 15 up and down by the driving force of the motor 13. The rotation of the rotary dresser 41 around the dresser rotation shaft 42 is performed by the driving force of the motor 46. The reciprocating movement of the rotary dresser 41 in the left-right direction is a well-known means for performing the work table 4 with the driving force of a servo motor or linear motor not shown.

  The dressing processing program for the grinding wheel 3 differs depending on the shape of the grinding wheel 3 attached to the surface grinding machine 1.

  For example, when the grinding wheel 3 is inclined on both sides of the outer periphery, as shown in FIG. 3, the grinding wheel 3 ′ indicated by the phantom line of the surface grinding machine is lowered and the lower end of the grinding wheel 3 indicated by the solid line is low. After being positioned so as to be lower than the top 41a of the tally dresser 41, the cutting of the rotating grinding wheel by the rotating cylindrical rotary dresser is started by reciprocating the work table to the left and right. At the same time, the grinding wheel is moved to the rear side or the front side while raising the grinding wheel rotating while the height is positioned downward by the dressing allowance, following the circular arc shape of the rotary dresser. When the profiling process is performed and the vertical line passing through the center of the width of the grinding wheel reaches the position passing through the dressing axis of the rotary dresser, the grindstone is continued while reciprocating the left and right of the worktable. I'm getting dressed up for a car While moving the grinding wheel backward or forward while lowering the grinding wheel following the circular arc shape of the rotary dresser while keeping the height downward, the rotary dresser follows the grinding wheel shape by moving the grinding wheel backward or forward. The grinding wheel is formed (see FIG. 4a).

When the grinding wheel 3 is inclined on one side surface of the outer periphery and the other surface is a vertical surface, as shown in FIG. 3, the grinding wheel 3 of the surface grinding machine is lowered and the lower end of the grinding wheel is a cylindrical rotary. After positioning the dresser 41 so as to be below the top 41a of the dresser 41, the rotary table is moved by reciprocating the work table to the left and right to start cutting of the rotating grinding wheel and the dressing allowance. The grinding wheel is moved backwards or forwards while the grinding wheel rotating while the height is positioned downward is moved following the circular arc shape of the rotary dresser, and the grinding wheel shape is copied. When the circular straight line passing through the center of the thickness width of the grinding wheel reaches the position where it passes the dress axis of the rotary dresser, the grinding wheel is rotated while continuing the reciprocating movement of the work table to the left and right. -The distance of the dresser radius Move to the rear side or the front side by the distance removed by the dress removal allowance, and then lower the grinding wheel downward from the position in contact with the horizontal outer periphery of the rotary dresser. The grinding wheel is molded by a rotary dresser following the shape of the grinding wheel that is dressed by moving the 2 mm grinding wheel up and down (see FIG. 4b).

When the outer peripheral surface is a straight flat grindstone, as shown in FIG. 3, the grinding wheel 3 ′ indicated by the phantom line is positioned below the top 41a of the cylindrical rotary dresser 41 by the dress amount (solid line). The wheel table 4 on which the grinding wheel forming apparatus 40 is placed is reciprocated in the left-right direction, and the rotary dresser 41 is cut into the outer peripheral surface of the grinding wheel 3. Multiply it. After dressing the outer peripheral surface of the grinding wheel, the grinding wheel is moved to the rear side or the front side by a distance obtained by removing the dressing allowance from the radial distance of the rotary dresser, and then the grinding wheel is moved to the rotary dresser. The grinding wheel is shaped by a rotary dresser following the shape of a grinding wheel that moves downward from a position that contacts the outer periphery in the horizontal direction and moves the grinding wheel up and down by 0.1 to 2 mm from the contact point. (See FIG. 4c).

  In these dressing steps, the grinding wheel 3 may be raised and lowered and moved back and forth repeatedly. In the grinding wheel forming process, the timing of executing it and the dressing program are stored in the storage unit of the control unit 24 in advance, the dressing program is selected from the operation panel 8 before the work grinding starts, and numerical control is performed. It is also possible to do this. At that time, before dressing, the outer diameter of the cylindrical rotary dresser 41 is measured with a micrometer, and the coordinate position of the vertical movement of the grinding wheel is corrected.

  As the cylindrical rotary dresser 41, abrasive grains such as diamond, green carborundum (GC), white alundum (WA), CBN, etc. are applied to the outer peripheral surface of a metal roll as a resin binder, metal bond. A diamond grindstone, a GC grindstone, a WA grindstone, or a CBN grindstone bonded with vitrified bonds is used. Examples of the resin binder include epoxy resin, phenoxy resin, and urethane resin.

The outer diameter of the rotary dresser 41 is 10 to 50 mm, which is sufficiently small compared to the diameter 100 to 800 mm of the grinding wheel 3. When the thickness of the working surface of the grinding wheel 3 is 0.05 to 20 mm, the grinding wheel width of the rotary dresser 41 is sufficient to be 5 to 30 mm. B - Tali - rotary peripheral velocity of the dresser 41, 1500～4000Min ^-1, rotary peripheral velocity of the grinding wheel 3 is 500～3000Min ^-1, preferably, Russia - Tali - towards the rotational peripheral speed of the dresser 41 Is higher than the rotational peripheral speed of the grinding wheel 3. For example, when the thickness of the working surface of the grinding wheel 3 is 0.05 to 2 mm, the rotational peripheral speed of the rotary dresser 41 is 3000 min ⁻¹ and the rotational peripheral speed of the grinding wheel 3 is 1500 min ⁻¹ . The stroke width of the work table 4 during dressing is 10 to 50 mm, the stroke speed is 200 to 1000 reciprocations / minute, and the dressing allowance is 2 to 5 μm.

  The grindstone forming apparatus of the present invention is compact and does not become an obstacle to grinding work by a work grinding wheel. In addition, since the horizontal rotation of the cylindrical rotary dresser 41 is combined with the longitudinal movement and vertical movement of the grinding wheel 3, dressing can be shortened and uneven wear of the rotary dresser 41 can be achieved. Can be prevented.

It is a perspective view of a surface grinder provided with a grindstone forming device. It is the side view which notched a part of surface grinder. It is a front view of a grindstone forming device. It is a dressing process figure which shows the positional relationship of the grinding wheel and cylindrical rotary dresser at the time of grinding wheel shaping | molding. It is a perspective view of a grindstone forming device. (Known)

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Surface grinder 2 Work 3 Grinding wheel 4 Worktable 6 Electromagnetic chuck 7 Saddle 10 Grinding wheel head 11 Grinding wheel spindle shaft 40 Grinding wheel forming device 41 Cylindrical rotary dresser 42 Dresser rotating shaft

Claims (2)

  A cylindrical rotary dresser is placed on one end of a worktable that can reciprocate in the left-right direction of the surface grinder so that the dresser rotation axis is in the front-rear direction and is parallel to the worktable surface. The grinding wheel mounted on the surface of the grinding wheel and rotatably supported by the grinding wheel spindle shaft of the grinding wheel head of the surface grinding machine is moved forward and backward and up and down with respect to the work table to the upper position of the work table. A grinding machine for surface grinders that can be provided.   The grinding wheel forming apparatus according to claim 1 is used to lower the grinding wheel of the surface grinding machine so that the lower end of the grinding wheel is located below the top of the cylindrical rotary dresser. -Start the cutting of the rotating grinding wheel by the cylindrical rotary dresser that rotates by reciprocating the bull left and right, and turn the rotating grinding wheel while positioning the height downward by the dressing allowance. -Move the grinding wheel to the rear side or the front side while raising it following the circular arc shape of the tally dresser to perform the grinding wheel shape copying process, and the vertical line passing through the center of the thickness width of the grinding wheel is cylindrical When it reaches the position where it passes through the dresser rotation axis of the rotary dresser, the grinding wheel is moved downward while the worktable continues to move back and forth while the height of the grinding wheel is positioned downward. Cylindrical By moving the grinding wheel backward or forward while descending following the circular arc shape of the tally dresser, the grinding wheel is shaped by the cylindrical rotary dresser according to the shape of the grinding wheel. A dressing method for a grinding wheel of a surface grinding machine, characterized in that a use surface is dressed in a predetermined shape on an outer peripheral surface of a cylindrical rotary dresser.

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