JP2018024031A - Truing device and truing method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a truing device having excellent operation efficiency and capable of reducing operation time.SOLUTION: There is provided a truing device T, in which the truing object is an abrasive wheel 2 comprised of end surfaces 22a and 22b, a cylindrical outer peripheral part 23, and corner parts 24a and 24b connecting the end surfaces 22a and 22b to the cylindrical outer peripheral part 23, and which includes a truer 40a, and a control unit 50 for relatively moving the abrasive wheel 2 and the truer 40a. The control unit 50 includes: a shape measuring control section 57 for measuring a shape of the abrasive wheel 2; a corner part correction amount calculation section 52 for calculating a correction amount of the corner parts 24a and 24b on the basis of the shape of the abrasive wheel 2 before truing and after truing; a corner part truing control section 55 for truing the corner parts 24a and 24b according to the correction amount; and a consecutive truing control section 56 for consecutively truing the corner parts 24a and 24b and the cylindrical outer peripheral part 23 after completing the truing of the corner parts 24a and 24b.SELECTED DRAWING: Figure 1A

Description

  The present invention relates to a truing device and a truing method for correcting a shape failure of a grinding wheel with a truer.

2. Description of the Related Art Conventionally, there is known a truing device that removes the outer periphery (grinding surface) of a grinding wheel whose shape has been lost after grinding with a truer and corrects the shape of the grinding wheel (see, for example, Patent Document 1).
In general, truing with a truing device is performed by traversing the outer periphery of the grinding wheel while rotating the truer.

JP-A-3-277468

  By the way, when performing truing, in order to reduce the load concerning a grinding wheel and a truer, the cutting amount to the grinding wheel by a truer is prescribed | regulated previously (for example, about 3 micrometers). Therefore, to correct the grinding wheel, it is necessary to traverse the truer along the outer periphery of the grinding wheel several times.

  Further, when the grinding wheel is ground, for example, at the pin portion of the crankshaft, the wear of the end face of the grinding wheel is larger than that of the cylindrical outer peripheral portion at a ratio of about 10: 1. Furthermore, in the cited document 1, only a continuous truing of one corner, a cylindrical outer peripheral portion and the other corner is described with a truer that rotates around an axis parallel to the rotation axis of the grinding wheel. It is necessary to perform truing of both end faces of the grinding wheel with another truer that rotates around an axis orthogonal to the rotational axis of the car. In this case, the correction amount of the end face is larger than that of the cylindrical outer peripheral portion at a ratio of 3: 1. Therefore, by grinding or truing, the shape of the corner portion of the grinding wheel is cut, and the shape of the corner portion collapses. The rate of shape collapse differs between the outer straight line portion and the curved corner portion, and the corner portion has a larger correction amount for correcting the shape. Therefore, the number of traversing times of the truer is determined according to the correction amount of the corner portion. For this reason, the straight portion with a small amount of correction often passes through without being brought into contact with the truer, and it cannot be said that the working efficiency of truing is good, and there is a problem that the working time of truing becomes long. .

  Therefore, the present invention has been made with an object of providing a truing apparatus and a truing method that can improve the working efficiency of truing and can shorten the working time.

(1. Trueing device)
The truing device of the present invention is a truing device for truing a grinding wheel including an end surface, a cylindrical outer peripheral portion, and a corner portion connecting the end surface and the cylindrical outer peripheral portion, and the truer, the grinding wheel, and the wheel A feed device that relatively moves the truer, and a control device that controls the feed device, the control device measuring the shape of the grinding wheel, and the shape of the grinding wheel before grinding An end face correction amount calculation unit that calculates a correction amount of the end face based on the wear amount of the end face guided by the shape of the grinding wheel before truing, the shape of the grinding wheel before grinding, and the shape before truing Cylindrical outer periphery correction amount calculation unit that calculates the correction amount of the cylindrical outer peripheral portion based on the wear amount of the cylindrical outer peripheral portion guided by the shape of the grinding wheel, the shape of the grinding wheel before grinding, and the correction of the end surface And a corner correction amount calculation unit for calculating the correction amount of the corner portion based on the shape of the grinding wheel after truing derived from the correction amount of the cylindrical outer peripheral portion, and the calculated correction amount of the corner portion A corner truing control unit for truing the corner portion leaving at least one cut amount; and after the truing of the corner portion, the corner portion and the cylindrical outer peripheral portion according to the at least one cut amount A continuous truing control unit for continuously truing.

(2. Trueing method)
The truing method of the present invention is a truing method for truing a grinding wheel having an end surface, a cylindrical outer peripheral portion, and a corner portion connecting the end surface and the cylindrical outer peripheral portion, and a shape measurement for measuring the shape of the grinding wheel. An end face correction amount step of calculating a correction amount of the end face based on a process, a shape of the grinding wheel before grinding, and a wear amount of the end face guided by a shape of the grinding wheel before truing; A cylindrical outer peripheral portion correction amount step for calculating a correction amount of the cylindrical outer peripheral portion based on the shape of the grinding wheel and the wear amount of the cylindrical outer peripheral portion guided by the shape of the grinding wheel before truing, and the grindstone before grinding A corner correction amount calculation step of calculating a correction amount of the corner portion based on the shape of the vehicle, the correction amount of the end face, and the shape of the grinding wheel after truing derived from the correction amount of the cylindrical outer peripheral portion. A corner truing step of performing truing of the corner portion by leaving at least one cut amount from the calculated correction amount of the corner portion, and after the truing of the corner portion, depending on the at least one cut amount And a continuous truing step of continuously truing the corner portion and the cylindrical outer peripheral portion.

  According to the truing device and the truing method of the present invention, after correcting the corner portion by leaving at least one incision amount from the correction amount of the corner portion, the corner portion and the cylindrical outer peripheral portion are continuously connected according to at least one incision amount. Since truing is performed, it is possible to reduce the occurrence of an oscillating state in which the truer and the grinding wheel are separated during truing, and the working efficiency of truing can be improved and the working time can be shortened.

1 shows a grinding apparatus according to a first embodiment. It is a cross section of a grinding wheel part of a grinding wheel of a grinding device of Drawing 1A mainly in the direction of a rotation axis. It is a flowchart which shows the flow of the truing process 1 by the control apparatus of a grinding device. It is a flowchart which shows the flow of the grindstone part measurement process by a control apparatus. It is a figure which shows the operation | movement which trues the 1st end surface and 2nd end surface of a grinding wheel in the truing process. It is a figure which shows the operation | movement which truing the 1st corner | angular part of a grinding wheel in a truing process 1, and a 2nd corner | angular part. It is a figure which shows the operation | movement which truing the 1st corner | angular part of a grinding wheel in a truing process 1, a cylindrical outer peripheral part, and a 2nd corner | angular part. It is a figure which shows the 1st example which truing the corner | angular part of the grinding wheel in the truing process. It is a figure which shows the 2nd example which truing the corner | angular part of the grinding wheel in the truing process. It is a figure which shows the 3rd example which truing the corner | angular part of the grinding wheel in the truing process 1. FIG. The grinding apparatus of 2nd this embodiment is shown. 7B is a cross section in the direction of the rotation axis of the truer of the truing device of FIG. 7A. It is a flowchart which shows the flow of the truing process 2 by the control apparatus of a grinding device. It is a figure which shows the operation | movement which trues the 1st corner | angular part of a grinding wheel in a truing process 2, and a 2nd corner | angular part. It is a figure which shows the operation | movement which truing the 1st end surface of a grinding wheel in a truing process 2, a 1st corner | angular part, and a cylindrical outer peripheral part. It is a figure which shows the operation | movement which truing the 2nd end surface and 2nd corner | angular part of a grinding wheel in truing process.

<First embodiment>
(1. Configuration of grinding device K)
The configuration of the grinding apparatus K will be described with reference to FIG. 1A. The grinding device K is a machine tool that performs grinding by moving the grinding wheel 2 relative to a workpiece W such as a crankshaft.

  The grinding device K includes a bed 1 fixed on the floor, and a grinding wheel base 10 provided on the bed 1 so as to be reciprocable along the X-axis direction, and a Z-axis direction intersecting the X-axis. And a table 11 provided so as to be reciprocally movable. Here, in this embodiment, the Z-axis direction is a direction along the rotation center axis C1 of the workpiece W, and the X-axis direction is a direction orthogonal to the rotation center axis C1 of the workpiece W.

  The grinding wheel base 10 is provided with a grinding wheel shaft rotation motor 15, and the grinding wheel 2 is rotatably provided by the grinding wheel shaft rotation motor 15. The grinding wheel axis C2 of the grinding wheel 2 is provided along the Z-axis direction.

  The grinding wheel 2 is formed in a disk shape and includes a grinding wheel core portion 20 and a grinding stone portion 21. The grindstone core portion 20 is a metal core such as iron or aluminum formed in a disc shape, and is detachably connected to the grindstone shaft of the grindstone shaft rotation motor 15 with a bolt or the like. The grindstone portion 21 is formed in an annular shape and is fixed to the outer peripheral surface of the grindstone core portion 20. The grindstone portion 21 is a portion that comes into contact with the workpiece W at the time of grinding, and is constituted by, for example, bonding super hard CBN abrasive grains to the outer periphery of the grindstone core portion 20 by vitrified bond or the like.

  A cross section (hereinafter, also referred to as “longitudinal cross section”) along the grindstone axis C2 of the grindstone portion 21 is as shown in FIG. 1B. The longitudinal section of the grindstone 21 includes a cylindrical outer peripheral portion 23 which is an outer peripheral surface, two end surfaces (first end surface and second end surface) 22a and 22b on both sides thereof, and a cylinder outer peripheral portion 23 and each end surface 22a and 22b. Two corner portions (first corner portion, second corner portion) 24 a and 24 b and an inner peripheral surface coupled to the outer periphery of the grindstone core portion 20 are provided.

  The cylindrical outer peripheral portion 23 is a surface parallel to the grindstone axis C2. The first and second end surfaces 22a and 22b are surfaces orthogonal to the grindstone axis C2. The first and second corner portions 24a and 24b are formed in a circular arc-shaped cross-sectional shape having a predetermined radius Ra. The first and second corner portions 24a and 24b are connected to the cylindrical outer peripheral portion 23 and the first and second end faces 22a and 22b so that the tangent lines are continuous. That is, the first and second corner portions 24a and 24b have a central angle of 90 °. The cylindrical outer peripheral portion 23, the first and second end surfaces 22a and 22b, and the first and second corner portions 24a and 24b are surfaces for appropriately contacting the workpiece W and performing grinding.

  As shown in FIG. 1A, on the table 11, a headstock 31 that supports one end of the workpiece W and is driven to rotate, and a tailstock 32 that rotatably supports the other end of the workpiece W are installed. Yes. The spindle 31 and the tailstock 32 support the workpiece W so that the rotation center axis C1 thereof coincides with the Z-axis direction, and the workpiece W is rotationally driven during grinding.

  On the table, the first truer unit 4a of the truing device T is provided so as to be reciprocally movable along the X-axis direction. The first truer unit 4a includes a rotatable first truer 40a and a drive device that rotationally drives the first truer 40a. The rotation axis C3 of the first truer 40a is provided along the X-axis direction. The first truer 40a is a known rotary truer. The first truer unit 4a provided in this way moves in the X-axis direction, that is, along the radial direction of the grinding wheel 2 without the workpiece W, so that the first and second end faces 22a, Each of 22b is truing.

  In addition, the first truer unit 4a is provided with a contact detector 45 for measuring the positions of the first end surface 22a of the grindstone portion 21 and the cylindrical outer peripheral portion 23 at the tip portion on the grinding wheel 2 side in the direction of the rotation axis C3. ing. The contact detector 45 is a known device and includes a disk-shaped detection board. The first end surface 22a of the grinding wheel 2 is applied to the outer periphery of the detection board, and the cylindrical outer peripheral portion 23 of the grinding wheel 2 is applied to the end surface of the detection board. An AE sensor 46 is provided for detecting vibrations at the time. The position of the first end surface 22a and the position of the cylindrical outer peripheral portion 23 are measured based on the vibration detection of the AE sensor 46. The contact detector 45 detects only the position of the first end face 22a without detecting the positions of both end faces of the grinding wheel 2 when detecting the position of the end face of the grinding wheel 2. Since the center in the width direction of the grinding wheel 2 is known, if the distance from the center in the width direction to the first end surface 22a is known, the position of the second end surface 22b can be calculated from the center in the width direction using that.

  Further, a second truer unit 4 b is provided on the head stock 31. The second truer unit 4b includes a rotatable second truer 40b and a drive device that rotationally drives the second truer 40b. The rotation axis C4 of the second truer 40b is provided along the Z-axis direction. The second truer 40b is a known rotary truer. The second truer unit 4b provided in this manner is configured to true the cylindrical outer peripheral portion 23 of the grinding wheel 2 and the first and second corner portions 24a and 24b.

  The grinding device K includes a control device 50. The control device 50 is constituted by a CPU, a ROM, and the like, and stores a numerical control (NC) program, grinding processing conditions, truing conditions, and the like. In the grinding process, the control device 50 NC-controls the X-axis position of the grinding wheel platform 10, the Z-axis position of the table 11, and the rotation of the workpiece W. The grinding device K grinds the outer peripheral surface of the workpiece W by controlling the position of each axis of the grinding wheel base 10 with respect to the workpiece W while rotating the grinding wheel 2 by the control device 50.

  The grinding apparatus K includes a grinding wheel base movement drive motor 60 that moves the grinding wheel base 10, a grinding wheel base movement encoder 61 that detects the position of the grinding wheel base 10, and a grinding wheel base movement that supplies a driving current to the grinding wheel base movement drive motor 60. Drive circuit 62, table movement drive motor 65 for moving table 11, table movement encoder 66 for detecting the position of table 11, and table movement drive circuit 67 for supplying a drive current to the table movement drive motor. Yes. Then, a position command is given from the control device 50 to the grindstone table moving drive circuit 62 and the table moving drive circuit 67.

  Further, in truing, the control device 50 controls the rotation of the first and second truers 40a and 40b by rotating the motors of the first and second truer units 4a and 4b. Further, the control device 50 performs NC control of the X-axis position of the grinding wheel 2, the X-axis position and Z-axis position of the first truer 40a, and the Z-axis position of the second truer 40b, and forms the shape of the grinding wheel 2. I do.

  As a functional configuration related to the control of truing, the control device 50 determines the correction amount of the cylindrical outer peripheral portion 23 based on the shape of the grinding wheel before truing and the wear amount of the cylindrical outer peripheral portion 23 guided by the shape of the grinding wheel 2 before grinding. A cylindrical outer peripheral portion correction amount calculating unit 51 for calculating is provided.

  As a functional configuration related to truing control, the control device 50 calculates a correction amount of the corner portion 24a based on the shape of the grinding wheel 2 before truing and the shape of the grinding wheel 2 after truing. 52.

  As a functional configuration related to truing control, the control device 50 calculates the correction amount of the end surface 22a based on the shape of the grinding wheel 2 before truing and the wear amount of the end surface 22a guided by the shape of the grinding wheel 2 before grinding. A correction amount calculation unit 53 is provided.

  The control device 50 includes an end surface truing control unit 54 that truws the first and second end surfaces 22a and 22b of the grinding wheel portion 21 of the grinding wheel 2 as a functional configuration related to truing control.

  The control device 50 includes a corner truing control unit 55 for truing the first and second corners 24a and 24b as a functional configuration relating to truing control.

  The control device 50 has, as a functional configuration relating to truing control, a continuous truing control unit 56 that continuously trues the first corner portion 24a, the cylindrical outer peripheral portion 23, and the second corner portion 24b, and the shape of the grinding wheel portion 21 of the grinding wheel 2. Is provided with a shape measurement control unit 57 for measuring the above.

  The truing device T of the present embodiment is a feed device for moving the first and second truer units 4a and 4b, the grinding wheel 2 and the first and second truer units 4a and 4b relative to each other in the X-axis and Z-axis directions. As shown below, a grinding wheel base movement drive motor 60, a grinding wheel base movement encoder 61, a grinding wheel base movement drive circuit 62, a table movement driving motor 65, a table movement encoder 66, a table movement driving circuit 67, and a control device 50 are provided. Including.

(2. Procedure of truing in the first embodiment)
The procedure and operation of the truing process 1 executed by the control device 50 of this embodiment will be described with reference to FIGS. 2 to 4C. In addition, truing is performed in the state in which there is no workpiece W in the grinding apparatus K.

  As shown in FIG. 2, the truing process 1 first measures the shape of the grinding wheel portion 21 of the grinding wheel 2 in a worn state after grinding (S10). The process of S10 is shifted to the grindstone part measurement process shown in FIG.

  As shown in FIG. 3, in the grinding wheel portion measurement process, first, the table 11 is moved to a position where the grinding wheel portion 21 of the grinding wheel 2 corresponds to the end surface of the detection board of the contact detector 45 (S <b> 30). In this process, the first truer unit 4a having the contact detector 45 is advanced to a predetermined position on the grinding wheel 2 side along the X-axis direction (see FIG. 1A).

  Subsequently, the grindstone platform 10 is advanced along the X-axis direction (S31). And it is determined whether the cylindrical outer peripheral part 23 of the grindstone part 21 was contact-detected by the contact detector 45 (S31). That is, it is determined whether or not the AE sensor 46 has detected vibration when the cylindrical outer peripheral portion 23 comes into contact with the end face of the detection panel of the contact detector 45. If it is negative determination (S31: no), the advancement of the grinding wheel base 10 of the process of S31 is continued.

  If it is affirmation determination (S32: yes), the advance of the grindstone base 10 will be stopped (S33). Next, the position of the wheel head 10 is read by the wheel head moving encoder 61 to detect the position of the wheel head 10 (S34). Then, the position of the cylindrical outer peripheral part 23 of the grindstone part 21 is calculated (S35). In this case, since the width of the detection panel, the diameter of the grinding wheel 2 and the position of the grinding wheel base 10 are known, if the diameter of the grinding wheel 2 changes, the position of the grinding wheel base 10 changes. Therefore, the position of the grinding wheel base 10 at this time Thus, the diameter of the grinding wheel 2 is known. From this, the position of the cylindrical outer peripheral portion 23 is calculated.

  Subsequently, the grindstone platform 10 is retracted by a predetermined amount along the X-axis direction (S36). Next, the table 11 is moved rightward by a predetermined amount along the Z-axis direction (S37). Next, the grindstone base 10 is advanced by a predetermined amount along the X-axis direction (S38). Thereafter, the table 11 is moved leftward along the Z-axis direction (S31).

  Then, it is determined whether or not the first end surface 22a of the grindstone portion 21 has been contact-detected by the contact detector 45 (S40). That is, it is determined whether or not the AE sensor 46 has detected vibration when the first end surface 22a contacts the outer periphery of the detection panel of the contact detector 45. If it is negative determination (S40: no), the table 11 of the process of S39 is continued leftward.

  If it is affirmation determination (S40: yes), the left advance of the table 11 will be stopped (S41). Next, the position of the table 11 is read by the table moving encoder 66 to detect the position of the table 11 (S42). Subsequently, the position of the first end surface 22a of the grindstone 21 is calculated (S43). In this case, since the diameter of the detection panel, the width of the grinding wheel 2 and the position of the table 11 are known, the position of the table 11 changes if the width of the grinding wheel 2 changes. You can see the width. Thereby, the position of the first end face 22a is calculated.

Then, the table 11 is moved rightward by a predetermined amount along the Z-axis direction (S44). Thereafter, the grindstone base 10 is retracted by a predetermined amount along the X-axis direction (S45), and the grindstone portion measurement process is terminated.
In this grinding wheel portion measurement process, if the position of the cylindrical outer peripheral portion 23 of the grinding wheel 2 and the position of the first end surface 22a are known, the position of the shape of the grinding wheel portion 21 can be known.

  After completion of the grinding wheel portion measurement process, as shown in FIG. 2, the wear amount of the first end surface 22a and the second end surface 22b and the wear amount of the cylindrical outer peripheral portion 23 are calculated (S11). Each amount of wear is calculated by subtracting the current position of the grinding wheel portion 21 before truing detected by measurement from the position of the grinding wheel portion 21 after the previous truing (before grinding).

  Next, the correction amounts of the first end surface 22a and the second end surface 22b are calculated according to the wear amounts of the first end surface 22a and the second end surface 22b. Further, the correction amount of the cylindrical outer peripheral portion 23 is calculated according to the wear amount of the cylindrical outer peripheral portion 23 (S12).

  Thereafter, truing is performed on the first end surface 22a of the grinding wheel 2 in accordance with the correction amount (S13). Next, the second end face 22b is trued (S14).

  As shown in FIG. 4A, the truing of the first end surface 22a by the process of S13 is such that the first truer 40a of the first truer unit 4a moves the first end surface 22a of the grindstone portion 21 from the first corner portion 24a side. The truing F10 by the linear track along the radial direction of the grinding wheel 2 is performed toward the inner peripheral side of the portion 21. In this case, the amount of cutting of the truer is specified (about 3 μm), the specified amount of cutting in the Z-axis direction at the radial reciprocating end of the grinding wheel 2 and the radial reciprocation of the grinding wheel 2. The movement is repeated a plurality of times to true the first end face 22a.

  Next, the first truer 40a relatively moves to a position corresponding to the second end surface 22b on the opposite side. In this case, it is possible to move at high speed, and the movement time is short. In the truing of the first end surface 22a by the process of S14, the first truer 40a moves the second end surface 22b in the radial direction of the grinding wheel 2 from the second corner portion 24b side toward the inner peripheral side of the grinding wheel portion 21. Truing F11 is performed by a linear trajectory along Also in this case, similarly to the truing of the first end face 22a, the predetermined amount of cutting in the Z-axis direction at the radial reciprocating end of the grinding wheel 2 and the radial reciprocation of the grinding wheel 2 are repeated a plurality of times. Truing the second end face 22b.

  Next, as shown in FIG. 2, the position of the first end face 22a after truing is measured (S15). This measurement is performed in the same manner as the processing of S38 to S45 of the grinding wheel portion measurement processing shown in FIG. Subsequently, the position of the second end face 22b after truing is calculated according to the measured position of the first end face 22a (S16).

  Thereafter, the correction amounts of the first corner portion 24a and the second corner portion 24b are calculated (S17). In this case, since the position, arc shape, and radius of the first corner portion 24a and the second corner portion 24b forming the arcuate cross section are known from the shape of the grindstone portion 21 before grinding after the previous truing, The correction amount of the corner portion 24 a is calculated from the correction amount of the first end surface 22 a and the correction amount of the cylindrical outer peripheral portion 23. Similarly, the correction amount of the second corner portion 24 b is calculated from the correction amount of the second end surface 22 b and the correction amount of the cylindrical outer peripheral portion 23. By subtracting the correction amount of the first end surface 22a, the correction amount of the second end surface 22b, and the correction amount of the cylindrical outer peripheral portion 23 from the shape of the grindstone portion 21 before grinding after the previous truing, the grindstone portion 21 after truing The shape of can be derived.

  The first corner 24a is trued according to the calculated correction amount (S18). In this case, the truing is performed a plurality of times while cutting a specified amount (about 3 μm). Further, when truing the first corner portion 24a, the truing of the first end surface 22a, the second end surface 22b, the cylindrical outer peripheral portion 23, and the second corner portion 24b is not performed.

  When the truing of the first corner 24a is completed, the truing of the second corner 24b is performed according to the calculated correction amount, similarly to the first corner 24a (S19). Further, when truing the second corner 24b, the truing of the first end face 22a, the second end face 22b, the cylindrical outer peripheral portion 23, and the first corner 24a is not performed.

  The truing of the first corner portion 24a by the process of S18 is performed according to the primary correction amount obtained by subtracting at least one incision amount from the calculated correction amount of the first corner portion 24a. As shown in FIG. 4B, the truing of the first corner portion 24a is such that the second truer 40b of the second truer unit 4b moves the first corner portion 24a from the first end surface 22a side toward the cylindrical outer peripheral portion 23 side. The truing F20 is performed by an arc locus along the arc-shaped cross section of the first corner portion 24a of the grindstone 21 after the previous truing. In this case, the second truer 40b repeats the predetermined amount (about 3 μm) at the reciprocating end of the arc locus and the reciprocating movement of the arc locus a plurality of times to true the first corner portion 24a.

  The second truer 40b relatively moves to a position corresponding to the second corner 24b on the opposite side. In this case, the movement time is short because of the high-speed movement. Then, the truing of the second corner portion 24b by the process of S19 is performed according to the primary correction amount obtained by subtracting at least one cutting amount from the calculated correction amount of the second corner portion 24b. The truing of the second corner portion 24b is performed by the second truer 40b of the second truer unit 4b after the previous truing from the second end surface 22b toward the cylindrical outer peripheral portion 23 side. Truing F21 is performed by an arc locus along the arc-shaped cross-sectional shape of the second corner portion 24b of the grindstone portion 21 before grinding. Also in this case, the second truer 40b trues the second corner portion 24b by repeating a predetermined amount (about 3 μm) incision at the reciprocating end of the arc locus and the reciprocating movement of the arc locus a plurality of times.

  As shown in FIG. 2, when the truing of the second corner portion 24b is finished, the first corner portion 24a, the cylindrical outer peripheral portion 23, and the second corner portion 24b are continuously trued (S20). This continuous truing subtracts the secondary correction amount obtained by subtracting the primary correction amount from the correction amount of the first corner portion 24a, at least one infeed amount, and the primary correction amount from the correction amount of the second corner portion 24b. This is performed according to the secondary correction amount.

  After all truing of the grindstone 21 has been completed, the shape and position of the grindstone 21 after the current truing are measured (S21). This is for use in calculating the correction amount of the grindstone 21 during the next truing. Thereafter, the truing process 1 is terminated.

  As shown in FIG. 4C, after the truing F21 of the second corner portion 24b ends, the second truer 40b returns to the position corresponding to the first corner portion 24a. This movement also takes a short time by moving at high speed. Then, in the continuous truing by the processing of S20, the second truer 40b has a linear shape along the grinding wheel axis of the grinding wheel 2 corresponding to the truing of the arcuate locus corresponding to the first corner portion 24a and the cylindrical outer peripheral portion 23. The continuous truing F30 in which the truing of the trajectory and the truing of the arc-shaped trajectory corresponding to the second corner portion 24b are performed is performed. In this case, the second truer 40b repeats a predetermined amount (about 3 μm) incision at the reciprocating end of the entire trajectory and a reciprocating movement of the entire trajectory a plurality of times to repeat the first corner 24a, the cylindrical outer peripheral portion 23 and the second Truing the corner 24b. Thereafter, the operation is terminated.

(3. Explanation of truing at the corner of the first example)
Next, the truing details of the first and second corner portions 24a and 24b will be described with reference to FIG.
The true truing is a truing in which the cutting direction of the second truer 40 b into the grinding wheel portion 21 is performed along the radial direction of the grinding wheel 2. In the figure, the truing of the first corner 24a will be mainly described, but the same applies to the second corner.

  The correction reference point P1 is calculated from the intersection of the shape and position of the grindstone 21 measured after the previous truing and before grinding and the position of the first end surface 22a measured after the truing of the first end surface 22a this time. Then, the desired shape G of the first corner 24a to be newly formed is set based on the calculated correction amount of the first corner 24a. The desired shape G is an arc convex shape having the same radius as the first corner portion 24a of the grindstone portion 21 after the previous truing.

  Then, the correction amount D of the first corner portion 24a along the radial direction of the grinding wheel 2 is calculated from the correction reference point P1 and the boundary point of the first end surface 22a of the desired shape G. In the figure, E2 is a correction amount along the radial direction of the cylindrical outer peripheral portion 23.

The truing F20 of the first corner portion 24 is the first correction amount obtained by subtracting the correction amount E2 of the cylindrical outer peripheral portion 23 or the one-time cutting amount of the first corner portion 24a from the correction amount D of the corner portion 24a. The truing F20 is started with an arc locus that truws the correction reference point P1 by the two truers 40b. Then, the second truer 40b repeatedly performs truing F20 on the circular arc locus while cutting along the radial direction of the grinding wheel 2 at the reciprocating end of the locus (arrow h).
The truing F20 ends with the desired shape G remaining with the correction amount E2 of the cylindrical outer peripheral portion 23 or the secondary correction amount corresponding to the one-time cutting amount of the first corner portion 24a. Thereafter, the desired shape G is formed by the continuous truing F30. Since the amount of correction D> the amount of one cut at the first corner 24a> the amount of correction E2, the secondary correction amount is preferably the amount of one cut at the first corner 24a. If the secondary correction amount is the correction amount E2, truing F20 is not performed, which is not preferable.

  In the figure, J1 represents the center point of the first corner 24a of the grindstone 21 after the previous truing, J2 represents the center point of the arc of the desired shape G, and J3 represents the center of the arc locus of the first truing F20. Indicates a point. The center point J3 moves toward the center point J2 along the radial direction of the grinding wheel 2 by repeating the truing F20.

(4. Explanation of corner truing in the second example)
As shown in FIG. 6, the true truing is performed from the shape of the first corner 24 a before truing toward the shape of the first corner 24 a of the desired shape G. That is, the cutting direction of the second truer 40b into the grindstone 21 is inclined with respect to the radial direction of the grinding wheel 2, and the center point J1 of the first corner 24a of the grindstone 21 after the previous truing The truing is performed in a direction along a straight line L1 connecting the center point J2 of the desired shape G. Therefore, the correction amount D1 of the first corner portion 24a is determined by the position of the first end surface of the grindstone portion 21 after the previous truing and the position of the first end surface 22a after truing along the direction along the straight line L1. Is the distance between.

  Then, the truing F20 is started by an arc trajectory passing through the correction reference point P1 by the second truer 40b in accordance with the primary correction amount obtained by subtracting the one-time cutting amount of the first corner portion 24a from the correction amount D1. Then, the second truer 40b repeatedly performs truing F20 of the arc locus while cutting in the direction along the straight line L1 at the reciprocating end of the locus (arrow h).

The truing F20 ends in a state in which a secondary correction amount corresponding to the cut amount of the first corner 24a is left for the desired shape G. Thereafter, the desired shape G is formed by the continuous truing F30. When the correction amount D1 is decomposed in the axial direction and the radial direction, the correction amount E1 and the correction amount E2 are obtained. That is, when the first corner portion 24a is corrected by the correction amount D1, the correction amount E2 is corrected in the radial direction. From this, it is desirable that the secondary correction amount is a single cut amount of the first corner portion 24a. If the secondary correction amount is the correction amount E2, truing F20 is not performed, which is not preferable.
In this way, according to the present truing, the correction amount D1 of the first corner portion 24a can be greatly reduced as compared with the truing correction amount D of the first example, and the number of truing operations can be reduced correspondingly. Is.

(5. Explanation of corner truing in the third example)
In the truing of the first example and the second example, the true trajectory of the truer is an arc trajectory having a central angle of right angle, and the swinger moves away from the corner of the grindstone. Therefore, in this truing, for each truing, a new truing excluding the correction amount E1 of the first end face 22a from the truing range surrounded by the shape of the corner 24a before truing and the shape of the corner 24a of the desired shape G. It is desirable to set a range and change the amount of movement of the truer based on the range.
FIG. 7 is an example in which the third example is applied to the truing of the second example shown in FIG. 6, and the movement of the truer is prevented from protruding from the first end surface 22 a of the grindstone 21. According to this, it is possible to improve the efficiency of truing by eliminating idling.

<Second embodiment>
A second embodiment of the present invention will be described based on FIGS. 8A to 10C. The basic configuration of the present embodiment is almost the same as that of the first embodiment, and differences will be mainly described. In the drawings, the same members are denoted by the same reference numerals, and the description of the same members is omitted.

(6. Configuration of grinding device K1)
As shown in FIG. 8A, the grinding device K <b> 1 is provided with a truer unit 4 c adjacent to the headstock 31 on the table 11. The truer unit 4c includes a rotatable truer 40c and a drive device that rotationally drives the truer 40c. The rotation axis C5 of the truer 40c is provided along the radial direction of the grinding wheel 2, that is, the X-axis direction. The truer unit 4c is configured to true the first and second end surfaces 22a and 22b, the cylindrical outer peripheral portion 23, and the first and second corner portions 24a and 24b of the grinding wheel 2, respectively.

  The spindle head 31 is provided with a contact detector 45a toward the grinding wheel head side. The contact detector 45a has substantially the same configuration as the contact detector 45 of the first embodiment. The contact detector 45a measures the positions of the first end surface 22a of the grindstone portion 21 and the cylindrical outer peripheral portion 23 by substantially the same operation as the contact detector 45 of the first embodiment.

  As a functional configuration related to truing control, the control device 50 has a correction amount of the cylindrical outer peripheral portion 23 based on the shape of the grinding wheel 2 before grinding and the wear amount of the cylindrical outer peripheral portion 23 guided by the shape of the grinding wheel 2 before truing. The cylindrical outer peripheral portion correction amount calculating unit 51 is provided.

  As a functional configuration related to truing control, the control device 50 has the shape of the grinding wheel 2 before truing, and the shape of the grinding wheel 2 after truing derived from the correction amount of the end faces 22a and 22b and the correction amount of the cylindrical outer peripheral portion 23. A corner correction amount calculation unit 52 that calculates a correction amount of the corner 24a is provided.

  As a functional configuration related to truing control, the control device 50 has a correction amount of the first end surface 22a based on the shape of the grinding wheel 2 before grinding and the wear amount of the first end surface 22a guided by the shape of the grinding wheel 2 before truing. An end face correction amount calculation unit 53 is provided.

  The control device 50 includes a corner truing control unit 55 for truing the first and second corners 24a and 24b as a functional configuration relating to truing control.

  As a functional configuration related to truing control, the control device 50 continuously trues the first end surface 22a, the first corner portion 24a, and the second cylindrical outer peripheral portion 23, and continuously connects the second end surface 22b and the second corner portion 24b. Then, a continuous truing control unit 56 that performs truing and a shape measurement control unit 57 that measures the shape of the grinding wheel portion 21 of the grinding wheel 2 are provided.

FIG. 8B shows a longitudinal section along the rotation axis C5 of the truer 40c.
The truer 40c is detachably attached to the distal end surface of the drive shaft 43 of the drive device with a bolt. The truer 40c is formed in a truncated cone shape. The smaller diameter side of the frustoconical shape of the truer 40 c is the base end side fixed to the distal end surface of the drive shaft 43, and the large diameter side of the frustoconical shape of the truer 40 c is the distal end side located on the opposite side of the drive shaft 43.

The truer 40 c includes a core 41 and an abrasive grain layer 42.
The core 41 is made of a metal material such as iron or aluminum and has a truncated cone shape. The core 41 is formed in a cup shape in which the diameter of the opening is enlarged in a cross-sectional view along the rotation axis C5. The core 41 has a base 411 positioned on the small diameter side of the truncated cone corresponding to the bottom of the cup and a hollow cylindrical tube portion 412 opening on the large diameter side of the truncated cone corresponding to the peripheral wall of the cup. The abrasive layer 42 is formed on the tapered outer peripheral surface 413 of the cylindrical portion 412 of the core 41. The abrasive layer 42 is formed by electrodeposition of abrasive grains such as granular diamond.

(7. Procedure of truing in the second embodiment)
The procedure and operation of the truing process 2 executed by the control device 50 of this embodiment will be described with reference to FIGS. 9 to 10C. As shown in FIG. 9, the truing process 2 first measures the shape and position of the grinding wheel 2 (S20). The measurement is performed using the contact detector 45a in the grinding wheel portion measurement process shown in FIG. Description of measurement is omitted.

  After the grinding wheel portion measurement process is completed, the wear amount of the first end surface 22a and the second end surface 22b and the wear amount of the cylindrical outer peripheral portion 23 are calculated (S51). Each amount of wear is calculated by subtracting the current position of the grinding wheel portion 21 before truing (after grinding) detected by measurement from the position of the grinding wheel portion 21 after the previous truing (before grinding).

  Subsequently, the correction amounts of the first end surface 22a and the second end surface 22b are calculated according to the wear amounts of the first end surface 22a and the second end surface 22b. Further, the correction amount of the cylindrical outer peripheral portion 23 is calculated according to the wear amount of the cylindrical outer peripheral portion 23 (S52).

Thereafter, the correction amounts of the first corner portion 24a and the second corner portion 24b are calculated (S53). In this case, since the position, arc shape, and radius of the first corner portion 24a and the second corner portion 24b forming the arcuate cross section are known from the shape of the grindstone portion 21 before grinding after the previous truing, The correction amount of the corner portion 24 a is calculated from the correction amount of the first end surface 22 a and the correction amount of the cylindrical outer peripheral portion 23. Similarly, the correction amount of the second corner portion 24 b is calculated from the correction amount of the second end surface 22 b and the correction amount of the cylindrical outer peripheral portion 23.
When the grindstone portion 21 before truing is measured, the correction amount E1 of the first end surface 22a is calculated from the wear amount of the first end surface 22a according to the information, and the first end surface 22a and the first corner portion 24a. A correction reference point P1 that is a boundary between the two is determined.

  The first corner 24a is trued according to the calculated correction amount (S54). In this case, the truing is performed a plurality of times while cutting a specified amount (about 3 μm). Further, when truing the first corner portion 24a, the truing of the first end surface 22a, the second end surface 22b, the cylindrical outer peripheral portion 23, and the second corner portion 24b is not performed.

  When the truing of the first corner 24a is completed, the truing of the second corner 24b is performed according to the calculated correction amount, similarly to the first corner 24a (S55). Further, when truing the second corner 24b, the truing of the first end face 22a, the second end face 22b, the cylindrical outer peripheral portion 23, and the first corner 24a is not performed.

  The truing of the first corner portion 24a by the process of S54 is performed according to a primary correction amount obtained by subtracting at least the remaining correction amount of the first end face 22a from the calculated correction amount of the first corner portion 24a. That is, the correction amount of the first end surface 22a = the remaining correction amount of the first end surface 22a + the wear amount of the first end surface 22a, and the first corner portion 24a corresponding to the wear amount of the first end surface 22a. The truing of the corner 24a is performed. As shown in FIG. 9A, the truing of the first corner portion 24a is performed when the truer 40c of the truer unit 4c moves the first corner portion 24a from the first end surface 22a side toward the cylindrical outer peripheral portion 23 side. Truing F20 is performed by an arc locus along the arc-shaped cross section of the first corner portion 24a of the grindstone 21 before truing and before grinding. In this case, the truer 40c repeatedly cuts a predetermined amount (about 3 μm) at the end of the arc locus on the first end face 22a side and moves along the arc locus from the first end face 22a side to the cylindrical outer peripheral portion 23 side a plurality of times. The first corner 24a is trued.

  The truer 40c relatively moves to a position corresponding to the opposite second corner 24b. In this case, the movement time is short because of the high-speed movement. Then, the truing of the second corner portion 24b by the process of S55 is performed according to the primary correction amount obtained by subtracting at least the remaining correction amount of the second end face 22b from the calculated correction amount of the second corner portion 24b. In other words, the correction amount of the second end face 22b = the remaining correction amount of the second end face 22b + the wear amount of the second end face 22b, and the correction amount of the second corner portion 24b corresponding to the wear amount of the second end face 22b. Truing of the corner 24b is performed. The truing of the second corner portion 24b is performed by the second truer 40b of the second truer unit 4b after the previous truing from the second end surface 22b toward the cylindrical outer peripheral portion 23 side. Truing F21 is performed by an arc locus along the arc-shaped cross-sectional shape of the second corner portion 24b of the grindstone portion 21 before grinding. Also in this case, the truer 40c repeats a predetermined amount (about 3 μm) of the circular arc locus at the end on the second end face 22b side and a movement along the arc locus from the second end face 22b side to the cylindrical outer peripheral portion 23 side a plurality of times. And truing the second corner 24b.

  As shown in FIG. 9, when the truing of the second corner portion 24b is completed, the first end face 22a, the first corner portion 24a, and the cylindrical outer peripheral portion 23 are continuously trued (S56). This continuous truing is performed according to the remaining correction amount of the first end face 22a and the secondary correction amount obtained by subtracting the primary correction amount from the correction amount of the first corner portion 24a.

  As shown in FIG. 10B, the truer 40c moves to a position corresponding to the inner peripheral side of the first end face 22a. This movement also takes a short time by moving at high speed. And the continuous truing by the process of S56, the truing of the linear locus along the radial direction of the grinding wheel 2 corresponding to the first end surface 22a, the truing of the arcuate locus corresponding to the first corner portion 24a, Corresponding to the cylindrical outer peripheral portion 23, continuous truing F40 in which truing of a linear locus along the grinding wheel axis of the grinding wheel 2 continues is performed. In this case, the truer 40c has a predetermined amount (about 3 μm) cut at the inner peripheral end of the first end surface 22a and the end of the cylindrical outer peripheral portion 23 on the second corner 24b side from the inner peripheral end of the first end surface 22a. Repeat truing multiple times to continuously truing. Thereafter, the operation is terminated.

  As shown in FIG. 9, when the continuous truing of the first end surface 22a, the first corner portion 24a, and the cylindrical outer peripheral portion 23 is completed, the second end surface 22b and the second corner portion 24b are continuously trued (S57). ). This continuous truing is performed according to the remaining correction amount of the second end face 22b and the secondary correction amount obtained by subtracting the primary correction amount from the correction amount of the second corner portion 24b.

  As shown in FIG. 10C, the truer 40c moves to a position corresponding to the inner peripheral side of the second end face 22b. This movement also moves at high speed. And the continuous truing by the process of S57 continuously trues the 2nd end surface 22b and the 2nd corner | angular part 24b from the inner peripheral side of the 2nd end surface 22b (F50). In this case, the truer 40c is provided with a specified amount (about 3 μm) of incision at the inner peripheral end of the second end surface 22b, and the end portion of the second corner portion 24b on the cylindrical outer peripheral portion 23 side from the inner peripheral end of the second end surface 22b. Repeat truing multiple times to continuously truing. Thereafter, the operation is terminated.

  In this embodiment, when truing the first or second corners 24a, 24b (F20, F21), truing (first example) in which the cutting direction is made along the radial direction of the grinding wheel, the original shape of the corners The amount of truing (second example) performed in the direction along the straight line connecting the center point and the center point of the desired shape, and the truing range that is the range of movement of the truer, excluding the abrasion amount due to end face grinding Any of the changing truing (third example) can be implemented.

(8. Effects of the embodiment)
In the first example, the second example, the third example, and the second embodiment of the first embodiment, the truing devices T and T1 include end surfaces 22a and 22b, a cylindrical outer peripheral portion 23, and end surfaces 22a and 22b and a cylindrical outer peripheral portion. The grinding wheel 2 provided with the corners 24a and 24b connecting to the wheel 23 is a truing target. The truing devices T, T1 include a truer 40a, 40b, 40c, a feed device that relatively moves the grinding wheel 2 and the truer 40a, 40b, 40c, and a control device 50 that controls the feed device. The control device 50 is based on the shape measurement control unit 57 that measures the shape of the grinding wheel 2, the shape of the grinding wheel 2 before grinding, and the wear amount of the cylindrical outer peripheral portion 23 that is guided by the shape of the grinding wheel 2 before truing. The cylindrical outer periphery correction amount calculating unit 51 for calculating the correction amount of the cylindrical outer peripheral portion 23, the shape of the grinding wheel 2 before truing, the correction amounts of the end faces 22a and 22b, and the truing derived from the correction amount of the cylindrical outer peripheral portion 23. Based on the shape of the subsequent grinding wheel 2, the corner correction amount calculation unit 52 that calculates the correction amount of the corners 24 a and 24 b, and at least one cut amount from the calculated correction amount of the corners 24 a and 24 b Corner truing control unit 55 for truing corners 24a and 24b, and after truing corners 24a and 24b, corners 24a and 24b and the outer circumference of the cylinder according to at least one cut depth And 23 continuously and a continuous truing control unit 56 for truing.

  The truing method using the truing devices T and T1 includes a shape measuring step (S10 in FIG. 2, S50 in FIG. 9) for measuring the shape of the grinding wheel 2, the shape of the grinding wheel 2 before grinding, and the truing method before truing. An end face correction amount process (S12 in FIG. 2, S52 in FIG. 9) for calculating the correction amount of the end faces 22a, 22b based on the wear amount of the end faces 22a, 22b guided by the shape of the grinding wheel 2, and the grinding wheel before grinding 2 and a cylindrical outer peripheral portion correction amount step of calculating a correction amount of the cylindrical outer peripheral portion 23 based on the wear amount of the cylindrical outer peripheral portion 23 guided by the shape of the grinding wheel 2 before truing (S12 in FIG. 2, FIG. 9). S52), a corner correction amount calculating step (S17 in FIG. 2) for calculating the correction amounts of the corner portions 24a and 24b based on the shape of the grinding wheel 2 after truing and the shape of the grinding wheel 2 before truing. , S53 in FIG. A corner truing process (S18 and S19 in FIG. 2 and S54 and S55 in FIG. 9) for truing the corners 24a and 24b while leaving at least one cut amount from the calculated correction amounts of the corners 24a and 24b. After the truing of the corners 24a and 24b, a continuous truing process (S20 in FIG. 2, FIG. 9) of continuously truing the corners 24a and 24b and the cylindrical outer peripheral part 23 according to at least one cut amount. S56).

  In other words, the corners 24a and 24b of the grinding wheel 2 having a large shape collapse are trued while leaving at least one incision amount from the correction amount of the corners 24 and 24b. After the truing is completed, the cylindrical outer peripheral portion 23 is truded continuously with the corner portions 24a and 24b, so that the occurrence of an idling state in which the grinding wheel 2 and the truers 40a, 40b, and 40c are separated during truing is reduced. The working efficiency of truing can be improved and the working time can be shortened.

  In the first example, the second example, and the third example of the first embodiment, the control device 50 wears the end faces 22a and 22b guided by the shape of the grinding wheel 2 before grinding and the shape of the grinding wheel 2 before truing. An end surface correction amount calculation unit 53 that calculates the correction amount of the end surfaces 22a and 22b based on the amount, and an end surface truing control unit 54 that truws the end surfaces 22a and 22b according to the correction amount of the end surfaces 22a and 22b are provided. The corner correction amount calculation unit 52 of the control device 50 calculates the correction reference point P1 from the intersection of the shape of the grinding wheel 2 before truing and the end surfaces 22a and 22b after truing the end surfaces 22a and 22b. Then, the corner truing control unit 55 starts truing with a trajectory for truing the correction reference point P1. According to this, suitable truing of the corner portions 24a and 24b can be performed.

  In the first example of truing at the corner (FIG. 5), in the truing devices T and T1 of the first and second embodiments, the corner truing control unit 55 of the control device 50 is the amount of correction of the corners 24a and 24b. From the above, a plurality of times of cutting of the above-described truers 40a, 40b, 40c along the radial direction of the grinding wheel 2 leaving at least one cutting amount, and a plurality of times of movement of the truers 40a, 40b, 40c along the corners 24a, 24b. And truing. According to this, reliable truing at the corner portions 24a and 24b is possible.

  In the second example (FIG. 6) of the truing of the corners 24a and 24b, the corner truing control unit 55 of the control device 50 has the shape of the corners 24a and 24b after truing from the shape of the corners 24a and 24b before truing. From the calculated correction amount of the corners 24a, 24b, a plurality of times of cutting of the above-described truers 40a, 40b, 40c and a plurality of times along the corners 24a, 24b are left to leave at least one calculated cutting amount. Truing is performed by the movement of the tourers 40a, 40b, and 40c. According to this, efficient truing at the corners 24a and 24b is possible.

  In the third example of truing of the corners 24a and 24b (FIG. 7), the corner truing control unit 55 of the control device 50 includes the shapes of the corners 24a and 24b before truing and the shapes of the corners 24a and 24b after truing. A new truing range is set by excluding the calculated correction amounts of the end faces 22a and 22b from the truing range surrounded by, and truing is performed by cutting and moving the truers 40a, 40b and 40c within the new truing range. . According to this, the working efficiency of truing in the corners 24a and 24b is improved, and the working time can be shortened.

  The truing device T of the first embodiment includes a first truer 40a that rotates about an axis orthogonal to the rotational axis of the grinding wheel 2 and a second truer 40b that rotates about an axis parallel to the rotational axis of the grinding wheel 2. The end surface truing control unit 54 truws the end surfaces 22a and 22b using the first truer 40a. The corner truing control unit 55 truws the corners 24a, 24b using the second truer 40b. The continuous truing control unit 56 continuously trues the corners 24a and 24b and the cylindrical outer peripheral portion 23 using the second truer 40b. According to this, each part of the grinding wheel 2 can be efficiently trued while being shared by the first and second tourers 40a and 40b.

  In the truing apparatus T1 of the second embodiment, the corner correction amount calculation unit 52 calculates the correction reference point P1 based on the shape of the grinding wheel 2 before truing and the wear amounts of the end faces 22a and 22b. The corner truing control unit 55 starts truing on a trajectory that allows the correction reference point P1 to be trued. According to this, suitable truing of the corner portions 24a and 24b can be performed.

  The truing device T1 of the second embodiment has a truncated cone shape and is large from the outer periphery of the core 41 that can rotate around the center line of the truncated cone shape and the base end (base 411) on the small-diameter side of the truncated cone shape. A cup-type tourer 40c having an abrasive layer 42 fixed to a tapered outer peripheral surface 413 extending over the outer periphery of the distal end (tubular portion 412) on the radial side is used. In the truer 40c, the rotation axis of the core 41 is directed in the radial direction of the grinding wheel 2 and the tip is disposed on the grinding wheel 2 side. The corner truing control unit 55 truws the corners 24a and 24b from the calculated correction amounts of the corners 24a and 24b, leaving the calculated correction amounts of the end faces 22a and 22b. Then, after the truing of the corner portions 24a and 24b is finished, the continuous truing control unit 56 continues the one end surface 22a, the one corner portion 24a, and the cylindrical outer peripheral portion 23 according to the calculated correction amount of the end surfaces 22a and 22b. The other end face 22b and the other corner 24b are continuously trued. According to this, simplification of the truing device can be achieved.

2: grinding wheel, 22a, 22b: end face, 23: cylindrical outer periphery, 24a, 24b: corner, 40a, 40b, 40c: truer, 41: core, 42: abrasive layer, 50: control device, 51: cylinder Peripheral part correction amount calculation unit, 52: Corner part correction amount calculation unit, 53: End surface correction amount calculation unit, 54: End surface truing control unit, 55: Corner part truing control unit, 56: Continuous truing control unit, 57: Shape measurement Control unit, K, K1: Grinding device, T, T1: Truing device, W: Workpiece

Claims (9)

A truing device for truing a grinding wheel including an end surface, a cylindrical outer peripheral portion, and a corner portion connecting the end surface and the cylindrical outer peripheral portion,
Tsurua,
A feed device that relatively moves the grinding wheel and the truer; and a control device that controls the feed device;
With
The controller is
A shape measurement control unit for measuring the shape of the grinding wheel;
An end face correction amount calculation unit that calculates a correction amount of the end face based on the shape of the grinding wheel before grinding and the wear amount of the end face guided by the shape of the grinding wheel before truing;
A cylindrical outer peripheral correction amount calculation unit that calculates a correction amount of the cylindrical outer peripheral portion based on the shape of the grinding wheel before grinding and the wear amount of the cylindrical outer peripheral portion guided by the shape of the grinding wheel before truing;
A corner portion that calculates the correction amount of the corner portion based on the shape of the grinding wheel before grinding, the correction amount of the end surface, and the shape of the grinding wheel after truing that is derived from the correction amount of the cylindrical outer peripheral portion. A correction amount calculation unit;
From the calculated correction amount of the corner, a corner truing control unit for truing the corner leaving at least one cut amount;
A continuous truing control unit for continuously truing the corner portion and the cylindrical outer peripheral portion according to the at least one cut amount after the truing of the corner portion;
Truing device with   The corner truing control unit is configured to leave the at least one incision amount from the calculated correction amount of the corner from the shape of the corner before truing toward the shape of the corner after truing. The truing apparatus according to claim 1, wherein truing is performed by cutting the truer and moving the truer a plurality of times along the corner.   The corner truing control unit sets a new truing range by excluding the calculated correction amount of the end face from the truing range surrounded by the shape of the corner before truing and the shape of the corner after truing. The truing apparatus according to claim 2, wherein truing is performed by the cutting and movement of the truer within the new truing range.   The corner truing control unit includes a plurality of times of cutting of the truer along the radial direction of the grinding wheel leaving the at least one amount of cut from a correction amount of the corner, and a plurality of times along the corner. The truing apparatus according to claim 1, wherein truing is performed by movement of the truer. The control device includes an end surface truing control unit that truws the end surface according to the calculated correction amount of the end surface,
The corner portion correction amount calculation unit calculates a correction reference point from an intersection of the shape of the grinding wheel before truing and the end surface after truing the end surface,
5. The truing apparatus according to claim 1, wherein the corner truing control unit starts truing on a trajectory for truing the correction reference point. 6. The corner portion correction amount calculation unit calculates a correction reference point based on the shape of the grinding wheel before the truing and the wear amount of the end face,
5. The truing apparatus according to claim 1, wherein the corner truing control unit starts truing on a trajectory for truing the correction reference point. 6. As the above-mentioned truer,
A first truer that rotates about an axis perpendicular to the rotational axis of the grinding wheel;
A second truer that rotates about an axis parallel to the rotational axis of the grinding wheel,
The end surface truing control unit is configured to true the end surface using the first truer;
The corner truing control unit is configured to true the corner using the second truer;
6. The truing apparatus according to claim 5, wherein the continuous truing control unit continuously trues the corner and the cylindrical outer peripheral portion using the second truer. As the above-mentioned truer,
A core having a truncated cone shape and rotatable around a center line of the truncated cone shape;
Using a cup-type truer provided with a tapered outer peripheral surface extending from the outer periphery of the base end of the truncated cone shape on the small diameter side of the core to the outer periphery of the distal end on the large diameter side,
The truer is arranged such that the rotation axis of the core is directed in the radial direction of the grinding wheel and the tip is disposed on the grinding wheel side,
The corner truing control unit truing the corner from the calculated correction amount of the corner, leaving the calculated correction amount of the end face,
The continuous truing control unit continuously trues one end face, the one corner part and the cylindrical outer peripheral part according to the calculated correction amount of the end face after the truing of the corner part, and the other 7. The truing device according to claim 6, wherein the end surface of the stool and the other corner are continuously trued. A truing method for truing a grinding wheel comprising an end face, a cylindrical outer peripheral part, and a corner part connecting the end face and the cylindrical outer peripheral part,
A shape measuring step for measuring the shape of the grinding wheel;
An end face correction amount step of calculating a correction amount of the end face based on the shape of the grinding wheel before grinding and the wear amount of the end face derived from the shape of the grinding wheel before truing;
A cylindrical outer peripheral portion correction amount step for calculating a correction amount of the cylindrical outer peripheral portion based on the shape of the grinding wheel before grinding and the wear amount of the cylindrical outer peripheral portion guided by the shape of the grinding wheel before truing;
A corner portion that calculates the correction amount of the corner portion based on the shape of the grinding wheel before grinding, the correction amount of the end surface, and the shape of the grinding wheel after truing that is derived from the correction amount of the cylindrical outer peripheral portion. Correction amount calculation step;
From the calculated correction amount of the corner portion, a corner truing step of truing the corner portion leaving at least one cut amount; and
A truing method comprising: a continuous truing step of continuously truing the corner portion and the cylindrical outer peripheral portion according to the at least one cut amount after the truing of the corner portion.

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