The disclosure of Japanese Patent Application No. 2015-142269 filed on Jul. 16, 2015 including the specification, drawings and abstract, is incorporated herein by reference in its entirety.
1. Field of the Invention
The invention relates to a grinding wheel.
2. Description of the Related Art
Grinding stones are conventionally used to grind journals, crank pins, and the like for an automotive crank shaft. See, for example, Japanese Patent Application Publication No. H11-188640 (JP H11-188640 A). A grinding stone disclosed in JP H11-188640 A has a disc-like member forming a grinding wheel and a grinding stone. The grinding stone is provided on an outer peripheral surface of the disc-like member, includes two types of grinding stone layers with different properties, and is divided into chips. Specifically, during grinding, high grinding resistance is offered at opposite end corners of the outer peripheral surface of the disc-like member in the direction of an axis of rotation and on opposite end surfaces of the outer peripheral surface. Thus, in these areas, a grinding stone layer is provided which is formed of grinding grains with a large grain size and which is unlikely to be worn away. No high grinding resistance is generated in a cylindrical portion between the opposite end corners of the outer peripheral surface. Thus, in this area, a grinding stone layer is provided which is formed of grinding grains that have a small grain size and are likely to worn away and that are expected to achieve high finishing accuracy.
In the above-described grinding stone, the two grinding stone layers are laminated to each other so as to have a joint surface in a direction orthogonal to the axis of rotation of the grinding wheel; one of the grinding stone layers is located at the end corners and on the end surfaces that involve high grinding resistance and that are likely to be significantly worn away, and the other grinding stone layer is located on the cylindrical portion that involves low grinding resistance and that is unlikely to be worn away. The grinding stone layers as described above are located adjacently to each other in the direction of the axis of rotation and simultaneously used for a grinding operation. Consequently, the grinding stone layers are worn away to different degrees, and thus a large step is likely to be formed at the joint surface, which is a boundary portion.
An object of the invention is to provide a grinding wheel that includes a plurality of types of grinding stone layers provided in an axial direction and having different properties, and that is capable of grinding a workpiece W having grinding target portions in different shapes with high finishing accuracy.
According to an aspect of the invention, a grinding wheel includes a disc-like member and a grinding stone layer disposed on an outer peripheral surface of the disc-like member to grind a workpiece. A grinding surface of the grinding stone layer includes a cylinder grinding surface formed parallel with an axis of rotation of the disc-like member, end grinding surfaces formed orthogonally to the axis of rotation and at respective opposite sides of the cylinder grinding surface in a direction of the axis of rotation, and corner grinding surfaces that connect the cylinder grinding surface to the end grinding surfaces such that the grinding surface is curved. The grinding stone layer includes a cylindrical-portion grinding stone layer including a part of the corner grinding surfaces and the cylinder grinding surface and end grinding stone layers including a remaining part of the respective corner grinding surfaces and the respective end grinding surfaces and having a property different from a property of the cylindrical-portion grinding stone layer. Joint surfaces are each formed by joining a boundary surface of the cylindrical-portion grinding stone layer and a boundary surface of the end grinding stone layer such that the boundary surfaces have a preset inclination to the axis of rotation. The joint surfaces are each formed to extend from a predetermined position in the corner grinding surface toward an interior of the grinding stone layer.
As described above, each joint surface between the cylindrical-portion grinding stone layer and the end grinding stone layer is inclined to the axis of rotation and formed to extend from the predetermined position in the corner grinding surface toward the interior of the grinding stone layer. Thus, even when a step extending in a direction orthogonal to the axis of rotation is formed between the cylindrical-portion grinding stone layer, which is likely to be significantly worn away, and the end grinding stone layer, which is only insignificantly worn away, the step is unnoticeable compared to a step that may be formed in the related art because the joint surface is positioned in the corner grinding surface. Consequently, a step transferred to the workpiece to be ground is also unnoticeable, and the workpiece is provided with an accurately ground surface.
The joint surface is inclined to the axis of rotation. Thus, when the grinding surface of the end grinding stone layer is trued, a distance from the grinding surface of the end grinding stone layer to the joint surface is prevented from being constantly reduced for each truing operation. Consequently, the grinding stone in the aspect of the invention can be used over a longer period of time and has a longer life than grinding stones in the related art.
The foregoing and further features and advantages of the invention will become apparent from the following description of example embodiments with reference to the accompanying drawings, wherein like numerals are used to represent like elements and wherein:
An embodiment of a grinding wheel according to the invention will be described below based on the drawings. As depicted in
The disc-like member 13 is driven to rotate around an axis of rotation CL of the grinding wheel 10 (in
As depicted in
Each of the corner grinding surfaces 17c is formed by connecting the cylinder grinding surface 17a and each end grinding surface 17b together with a curve having a given radius of curvature R, that is, a circular arc-shaped curve. The corner grinding surfaces 17c grind round corners 49 (see
The circumferential grinding stone chip A (grinding stone layer 16) includes one cylindrical-portion grinding stone layer 21 and two end grinding stone layers 22. As depicted in
As depicted in
The boundary surfaces 22a, 21a facing each other are joined together to form the circumferential grinding stone chip A. A combination of the boundary surface 22a and the boundary surface 21a joined together is referred to as a joint surface 23. As described below in detail, in this case, the joint surface 23, particularly a part of the joint surface 23 corresponding to an area where the corner grinding surface 17c is formed, is formed to have a preset inclination to the axis of rotation CL. The joint surface 23 referred to below represents this part of the joint surface 23. As depicted in
Each corner grinding surface 17c is formed to have a circular arc shape having a predetermined radius of curvature R in a longitudinal section thereof as described above (see
In the above description, the inclination angle α° (see
The truing operation TL is a well-known technique for grinding the grinding surface (the first grinding surface 51 and the second grinding surface 52) of the grinding stone that has been roughened to a given degree or higher as a result of a grinding operation on the workpiece W over a predetermined time, in order to correct the surface state to obtain a new surface. Therefore, detailed descriptions are omitted. The truing amounts L1, L2 refer to the depth of cutting with respect to the uncorrected state of the surface of the grinding stone.
As depicted in
As depicted in
Although not described above, in the present embodiment, grinding stone layers referred to as mixing portions 24 are formed on both sides of the joint surface 23 on the border between the cylindrical-portion grinding stone layer 21 and each end grinding stone layer 22 as depicted in
The mixing portions 24 contain both the bond 15 and the bond 20 in a mixed manner. Therefore, the mixing portions 24 have the properties of both the end grinding stone layer 22 and the cylindrical-portion grinding stone layer 21. The likelihood of wear of the mixing portions 24 is substantially intermediate between the likelihood of wear of the end grinding stone layer 22 and the likelihood of wear of the cylindrical-portion grinding stone layer 21. In the present embodiment, the mixing portions 24 more preferably have a smaller width M. The width of each of the mixing portions 24 (M/2) preferably enables up to one or two super-abrasives 14, 19 from the end grinding stone layer 22 and the cylindrical-portion grinding stone layer 21 to be contained in the mixing portion 24.
Consequently, an area of the first grinding surface 51 where grinding can be performed using only the composition of the end grinding stone layer 22 corresponds to the entire first grinding surface 51 except for the mixing portion 24 located on the first grinding surface 51 side with respect to the joint surface 23 (the width=M/2). As is the case with the first grinding surface 51, an area of the second grinding surface 52 where grinding can be performed using only the composition of the cylindrical-portion grinding stone layer 21 corresponds to the entire second grinding surface 52 except for the mixing portion 24 located on the second grinding surface 52 side with respect to the joint surface 23 (the width=M/2). The mixing portions 24 may be omitted if the circumferential grinding stone chip A can be produced without the mixing portions 24.
The end grinding stone layers 22, the cylindrical-portion grinding stone layer 21, and the mixing portions 24 form the circumferential grinding stone chip A. The circumferential grinding stone chips A are arranged on the outer peripheral surface of the disc-like member 13 in the circumferential direction to form the grinding stone layer 16.
Now, a manufacturing method for the circumferential grinding stone chip A will be described in brief To manufacture the end grinding stone layers 22, first, powder that is a mixture of the super-abrasives 14, the bond 15, and the like for the end grinding stone layers 22 is pressed using a press machine and molded into grinding stone chips for the end grinding stone layers 22. The press-molded grinding stone chips are dried, and after the drying, the resultant grinding stone chips are sintered to complete the end grinding stone layers 22. The cylindrical-portion grinding stone layer 21 is manufactured by a method similar to the method for manufacturing the end grinding stone layers 22 except that the super-abrasives 14 and the bond 15 for the end grinding stone layers 22 are changed to the super-abrasives 19 and the bond 20 for the cylindrical-portion grinding stone layer 21.
Next, for junction, the end grinding stone layers 22 and the cylindrical-portion grinding stone layer 21 are sintered with the boundary surfaces 22a, 21a of the end grinding stone layers 22 and the cylindrical-portion grinding stone layer 21 in contact with each other. The bond 15 and the bond 20 are melted near a contact portion between the boundary surfaces 22a, 21a of the sintered end grinding stone layers 22 and cylindrical-portion grinding stone layer 21. In this state, the super-abrasives 14, 19 from each end grinding stone layer 22 and the cylindrical-portion grinding stone layer 21 are mixed together as described above to form the mixing portions 24 at the respective opposite sides of the joint surface 23, and thus the circumferential grinding stone chips A are formed. The thus formed 16 circumferential grinding stone chips A are consecutively stuck to the outer peripheral surface of the disc-like member 13 all along the circumference thereof with an adhesive (not depicted in the drawings), so that the grinding wheel 10 is formed.
Now, a grinding machine 25 on which the grinding wheel 10 is installed to grind the workpiece W will be described based on
A wheel spindle stock 34 is slidably disposed on the bed 26 and moved in an X axis direction crossing the Z axis at right angles by a servo motor 35 via a ball screw. A wheel spindle 36 is rotatably borne on the wheel spindle stock 34 and rotationally driven by a built-in motor 37. A center hole 38 drilled in the disc-like member 13 of the grinding wheel 10 is fitted over a tip of the wheel spindle 36. The grinding wheel 10 is fixed to the wheel spindle 36 using a bolt.
A CNC apparatus 40 is connected to drive circuits 41 to 44 for the servo motors 28, 32, 35, and the built-in motor 37. The CNC apparatus 40 sequentially executes a grinding NC program during grinding to cause the grinding wheel 10 to grind the workpiece W.
When causing the grinding wheel 10 to grind the workpiece W, the CNC apparatus 40 executes the grinding NC program to output a rotation command to rotate the grinding wheel 10 at a high rotation speed, to the drive circuit 44 for the built-in motor 37. The CNC apparatus 40 outputs a rotation command to rotate the workpiece W at a peripheral velocity suitable for grinding, to the drive circuit 42 for the servo motor 32, which rotationally drives the main spindle 31. Next, a feed command to move the table 27 in the Z axis direction to a position where the workpiece W faces the grinding wheel 10 is output to the drive circuit 41 for the servo motor 28.
When the grinding wheel 10 is placed to face a grinding area of the workpiece W, a command to move the wheel spindle stock 34 in the X axis direction at a roughing feeding speed is output to the drive circuit 43 for the servo motor 35. Thus, the grinding wheel 10 grinds the workpiece W while being fed with coolant through a coolant nozzle not depicted in the drawings.
Now, grinding of the workpiece W by the grinding wheel 10 will be described in detail. As described above, the workpiece W is a crank shaft, and a grinding target area is a recessed portion 50 of the crank shaft, for example, an outer peripheral surface of a crank journal 45 depicted in
As depicted in
In the grinding stone layer 16 of the grinding wheel 10, the joint surfaces 23 are each formed which corresponds to the boundary between the first grinding surface 51 of the end grinding stone layer 22, which is relatively insignificantly worn away, and the second grinding surface 52 of the cylindrical-portion grinding stone layer 21, which is relatively significantly worn away, as depicted in
When the grinding wheel 10 formed as described above grinds the inside of the recessed portion 50, the first grinding surface 51 and the second grinding surface 52, between which the joint surface 23 is sandwiched, are worn away to some extent by grinding resistance offered by the workpiece W. Due to a difference in the amount of wear between the first grinding surface 51 and the second grinding surface 52, a step is formed therebetween. However, the step Di is formed in the corner grinding surface 17c and shaped as depicted in
Now, the effects of the truing operation TL performed on the grinding stone layer 16 during a grinding operation will be described based on
The surface position of the joint surface 23 is located slightly closer to the end grinding surface 17b than the intersection position T between the corner grinding surface 17c and the line LE passing through the circular arc center O of the corner grinding surfaces 17c and extending in the direction at an angle of 45° to the axis of rotation CL, as described above. The long dashed double-short dashed lines illustrate states of the grinding stone layer 16 after each truing operation TL, namely each truing operation TL1 and each truing operation TL2, performed on the grinding stone layer 16 under the above-described conditions. The long dashed double-short dashed lines illustrate the first grinding surface 51 and the second grinding surface 52 resulting from the first to fourth truing operations from right toward left in
As seen in
In the above-described embodiment, the grinding wheel 10 includes the disc-like member 13 and the grinding stone layer 16 disposed on the outer peripheral surface of the disc-like member 13 to grind the workpiece W. The grinding surface of the grinding stone layer 16 includes the cylinder grinding surface 17a formed parallel with the axis of rotation CL of the disc-like member 13, the end grinding surfaces 17b formed orthogonally to the axis of rotation CL and at the respective opposite sides of the cylinder grinding surface 17a in a direction of the axis of rotation CL, and the corner grinding surfaces 17c that connect the cylinder grinding surface 17a to the end grinding surfaces 17b such that the grinding surface is curved. The grinding stone layer 16 includes the cylindrical-portion grinding stone layer 21 including a part of the corner grinding surfaces 17c and the cylinder grinding surface 17a and the end grinding stone layers 22 including the remaining part of the respective corner grinding surfaces 17c and the respective end grinding surfaces 17b and having a property different from the property of the cylindrical-portion grinding stone layer 21. The joint surfaces 23 are each formed by joining the boundary surface 21a of the cylindrical-portion grinding stone layer 21 and the boundary surface 22a of the end grinding stone layer 22 such that the boundary surfaces 21a, 22a have a preset inclination to the axis of rotation CL. The joint surfaces 23 are each formed to extend from a predetermined position in the corner grinding surface 17c toward the interior of the grinding stone layer 16.
As described above, each joint surface 23 between the cylindrical-portion grinding stone layer 21 and the end grinding stone layer 22 is inclined to the axis of rotation CL and formed to extend from the predetermined position in the corner grinding surface 17c toward the interior of the grinding stone layer 16. In other words, the joint surface 23 is provided in a portion of the corner grinding surface 17c that is close to the surface orthogonal to the axis of rotation CL (the end grinding surface 17b) instead of a portion of the corner grinding surface 17c that is close to the surface parallel to the axis of rotation CL (the cylinder grinding surface 17a). Thus, even when the step Di is formed between the cylindrical-portion grinding stone layer 21, which is significantly worn away, and the end grinding stone layer 22, which is only insignificantly worn away, the step Di is unnoticeable compared to a step that may be formed in the related art in which the joint surface is orthogonal to the axis of rotation. Even if, for example, the end grinding stone layer 22 is more significantly worn away than the cylindrical-portion grinding stone layer 21 as in the related art, the step Di formed between the cylindrical-portion grinding stone layer 21 and the end grinding stone layer 22 is unnoticeable compared to the step that may be formed in the related art. Consequently, the step transferred to the workpiece W to be ground is also unnoticeable, and the workpiece W is provided with an accurately ground surface.
The joint surface 23 is inclined to the axis of rotation CL. Thus, when the truing operation TL is performed on the grinding surfaces of the cylindrical-portion grinding stone layer 21 and the end grinding stone layer 22, the distance from the grinding surface of the end grinding stone layer 22 (the end grinding surface 17b) to the joint surface 23 is prevented from being constantly reduced for each truing operation TL. Consequently, the grinding stone in the present embodiment can be used over a longer period of time and has a longer life than grinding stones in the related art.
In spite of a predetermined number of truing operations TL, the inclination of the joint surface 23 is effective for maintaining the same distance from the grinding surface (end grinding surface 17b) of each of the end grinding stone layers 22, which grind the side surfaces 46, 47 of the recessed portion 50 of the workpiece W, to the joint surface 23, specifically, the same distance to the mixing portions 24 formed at the respective opposite sides of the joint surface 23 (see B in
In the above-described embodiment, the longitudinal section of each of the corner grinding surfaces 17c of the grinding stone layer 16 is shaped like a circular arc.
The surface position of each of the joint surfaces 23 on the corner grinding surface 17c is located closer to the end grinding surface 17b than the intersection position T between the corner grinding surface 17c and the line LE passing through the circular arc center O of the corner grinding surfaces 17c and extending in the direction at an angle of 45° to the axis of rotation CL. In other words, the surface position of the joint surface 23 lies in a portion of the corner grinding surface 17c that is close to a portion thereof orthogonal to the axis of rotation CL instead of a portion of the corner grinding surface 17c that is close to a portion thereof parallel to the axis of rotation CL. Consequently, even when a step is formed across the opposite sides of the joint surface 23 in the direction of the axis of rotation CL so as to extend in a direction orthogonal to the axis of rotation CL, the step is unnoticeable.
In the above-described embodiment, the truing amount L2 of each truing operation on the cylindrical-portion grinding stone layer 21 is smaller than the truing amount LA of each truing operation on each end grinding stone layer 22. An angle of the inclination between the axis of rotation CL and each of the joint surfaces 23 is set to be smaller than 45°. As described above, the truing amounts L1, L2 of truing operations on the grinding stone layers 21, 22 are determined based on the amounts of wear of the grinding stone layers 21, 22 for the product to be ground, and the inclination angle α° is set in accordance with the truing amounts L1, L2. Thus, an optimum similar relation is likely to be constantly maintained among each end grinding surface 17b, the cylinder grinding surface 17a, the corresponding joint surface 23. This facilitates extension of the life of the grinding stone.
In the above-described embodiment, the 16 circumferential grinding stone chips A are arranged in the circumferential direction to form the grinding stone layer 16. However, any number of the circumferential grinding stone chips A may be provided. Alternatively, the grinding stone layer 16 may be integrally formed in the circumferential direction instead of being divided into chips.
In the above-described embodiment, the longitudinal section of each of the corner grinding surfaces 17c of the grinding stone layer 16 is shaped like a circular arc. The surface position of the joint surface 23 on the corner grinding surface 17c is located closer to the end grinding surface 17b than the intersection position T between the corner grinding surface 17c and the line passing through the circular arc center O of the corner grinding surfaces 17c and extending in the direction at an angle of 45° to the axis of rotation CL. However, the invention is not limited to this aspect. The joint surface 23 may be located at any surface position as long as the surface position lies on the corner grinding surface 17c. This also produces effects similar to the effects of the present embodiment.
In the above-described embodiment, the inclination angle α° to the axis of rotation CL is smaller than 45°. However, the invention is not limited to this aspect. The inclination angle α° may be equal to or larger than 45°. This also produces effects similar to the effects of the present embodiment.
Number | Date | Country | Kind |
---|---|---|---|
2015-142269 | Jul 2015 | JP | national |