The invention relates to a grinding wheel which includes an annular grindstone member fitted to a disc member.
There is provided a grinding wheel for grinding a work surface, which has an annular grindstone member fitted on an outer peripheral surface of the disc member (see, for example, Patent Document 1).
This grinding wheel is enabled to grind the work surface while the grinding member is rotating about the center of the circle of the disc member and the outer peripheral surface is kept in contact with the work surface. If the work surface has a recessed shape, the work surface is ground by the side surface of the grindstone member.
Patent Document 1
Patent Application Publication Laid-Open No. Hei 5-31674
According to the above-described conventional grinding wheel, it is difficult for the grinding fluid to enter between the side surface of the grindstone member and the work surface. As a result, the temperature on the work surface excessively rises. Therefore, a lot of grinding fluid at a high pressure is sprayed between the side surface of the grindstone member and the work surface, which enables the grinding fluid to enter between the side surface of the grindstone member and the work surface. This, however, causes a problem that a large supply amount of grinding fluid is required and generation of mist increases.
The invention solves the above-described problem, and is directed to a grinding wheel which enables sufficient supply of the grinding fluid on the surface of the grindstone member and reduces a supply amount of grinding fluid and generation of mist.
To solve the problem, the invention provides a grinding wheel including: a disc member; and an annular grindstone member fitted on an outer peripheral surface of the disc member. The disc member has a fluid-supply hole formed therethrough from a first side surface to a second side surface thereof. The fluid-supply hole has an outlet opening through an outer peripheral portion of the first side surface; and an inlet opening which is open through the second side surface and is disposed at an inner position of the outlet opening in a radial direction of the disc member. The second side surface is formed with an outer peripheral wall which is disposed at an outer position of the inlet opening in the radial direction of the disc member and projects along an outer peripheral portion of the disc member.
To solve the problem, another aspect of the invention provides a grinding wheel including: a disc member; and an annular grindstone member fitted on an outer peripheral surface of the disc member. The disc member has a first fluid-supply hole and a second fluid-supply hole which are formed through the disc member from a first side surface to a second side surface of the disc member and which are formed alternately in a peripheral direction of the disc member. The first fluid-supply hole has an outlet opening through an outer peripheral portion of the first side surface; and an inlet opening which is open through the second side surface and is disposed at an inner position of the outlet opening in a radial direction of the disc member. The second fluid-supply hole has an outlet opening through an outer peripheral portion of the second side surface; and an inlet opening which is open through the first side surface and is disposed at an inner position of the outlet opening in a radial direction of the disc member. The first side surface and second side surface of the main body are formed with outer peripheral walls, respectively which are disposed at outer positions of inlet openings in a radial direction of the disc member and project along an outer peripheral portion of the disc member. Outlet openings are open through the outer peripheral walls, respectively.
To solve the problem, another aspect of the invention provides a grinding wheel including: a disc member; and an annular grindstone member projectingly provided at an outer peripheral portion on a first side surface of the disc member. The disc member is formed with a fluid-supply hole extending therethrough from the first side surface to a second side surface thereof. The fluid-supply hole has an outlet opening through an outer peripheral portion of the first side surface; and an inlet opening which is open through the second side surface and is disposed at an inner position of the outlet opening in a radial direction of the disc member. The second side surface is formed with an outer peripheral wall which is disposed at an outer position of the inlet opening in a radial direction of the disc member and projects along the outer peripheral portion of the disc member.
According to the aspects, while the grinding wheel is rotating about the center of the circle of the disc member, the grinding fluid is supplied onto the side surface of the disc member. The grinding fluid flows on the side surface outwardly in a radial direction under a centrifugal force, and is blocked on the outer peripheral wall. The grinding fluid, being reserved inside the outer peripheral wall, flows into the fluid-supply hole from the inlet opening disposed at an inner position of the outer peripheral wall to be jetted from the outlet opening of the opposite side surface to the outer peripheral portion of the disc member.
In this manner, the grinding fluid is jetted to the vicinity of the side surface of the grindstone member. When the side surface of the grindstone member grinds a work surface, the grinding fluid is sufficiently supplied onto the side surface of the grindstone member without supplying the grinding fluid at a high pressure, thereby remarkably reducing generation of mist.
The grinding fluid, being supplied onto the side surface of the disc member, is blocked on the outer peripheral wall and is guided to the inlet opening of the fluid-supply hole, thereby reducing a supply amount of the grinding fluid.
The fluid-supply hole is formed from the inlet opening to the outlet opening and in a straight-line in a radial direction of the disc member, thereby enabling the grinding fluid to smoothly flow through the fluid-supply hole.
In the grinding wheel, the inner peripheral surface on the outer peripheral wall is formed with an inclined surface of a reverse-taper which has a diameter decreased from a proximal end side to a distal end side thereof, and the side surface on the disc member and the inner peripheral surface on the outer peripheral wall form a recessed corner in a wedge shape. According to this construction, the outer peripheral wall securely blocks the grinding fluid and guides the grinding fluid to the inlet opening of the fluid-supply hole.
The above grinding wheel has a side surface formed with a recessed groove which is disposed at a position corresponding to the outlet opening and extends from an inner peripheral surface to an outer peripheral surface of the grindstone member. This side surface of the grindstone member enables the grinding fluid to be securely supplied, and the grinding fluid to be supplied onto the outer peripheral surface of the grindstone member through the recessed groove.
The grinding wheel of the invention sufficiently supplies the grinding fluid onto the surface of the grindstone member, and remarkably reduces a supply amount of the grinding fluid and generation of mist.
The specific descriptions will be given of embodiments of the present invention by appropriately referring to the drawings.
Note that the same elements are attached with the same reference numerals in each description of embodiments, respectively, so as to omit redundant description.
A grinding wheel 1 of the first embodiment, as shown in
The disc member 10 has a center portion joined to a rotation shaft as not shown in the figures, and serves as a member to rotate about the center of the circle as a rotation center. This disc member 10 is a metal component as made of a steel material, and has a sufficient rigidity. The center portion of the disc member 10 is formed with a flanged surface 15 to which the tip surface of the rotation shaft is fixed. The flanged surface 15 defines fitting holes 15a in which bolts for fixing the disc member 10 and the rotation shaft to each other are inserted, respectively.
As shown in
Each outer peripheral wall 11 has an inner peripheral surface 11a that is an inclined surface of a reverse-taper having a diameter decreased from the proximal end side thereof (inside in a thickness direction) to the distal end side thereof (outside in a thickness direction). The side surfaces 10A, 10B of the disc member 10 and the inner peripheral surfaces 11a of the outer peripheral walls 11 form wedge-shaped recessed corners, respectively.
As shown in
As shown in
The first fluid-supply hole 12A, as shown in
The outlet opening 13 is open through the side surface 11b on the outer peripheral wall 11. The inlet opening 14 is open at the position adjacent to the inner peripheral surface 11a of the outer peripheral wall 11. Thus, the inlet opening 14 is disposed at an inner position of the outlet opening 13 in a radial direction of the disc member 10. Therefore, the first fluid-supply hole 12A is inclined to a width direction of the disc member 10 (horizontal direction of
The second fluid-supply hole 12B, as shown in
The second fluid-supply hole 12B is constructed such that the first fluid-supply hole 12A (see
The grindstone member 20, as shown in
As shown in
As shown in
According to the above-constructed grinding wheel 1, as shown in
It is noted that fluid-supply nozzles 30 are constructed so as to jet the grinding fluid on both side surfaces 10A, 10B at the upstream from the contact positions of the grinding wheel 1 and the work surface in a rotational direction.
The grinding fluid on both side surfaces 10A, 10B is blocked on the inner peripheral surfaces 11a of the peripheral walls 11 and is guided to the inlet opening 14 of the second side surface 10B to flow from the inlet opening 14 into the first fluid-supply hole 12A.
The grinding fluid flows through the first fluid-supply hole 12A to be jetted from the outlet opening 13 to the side surface 11b of the outer peripheral wall 11 to be supplied onto the side surface 20A of the grindstone member 20.
In the second fluid-supply hole 12B as shown in
As shown in
The following description is given of the steps for grinding a crank shaft 90 by use of the grinding wheel 1 of the first embodiment.
To be specific, as shown in
While the grinding wheel 1 is rotating, the grinding fluid is jetted out of the fluid-supply nozzles 30, 30 on both side surfaces 10A, 10B of the disc member 10. The grinding fluid being jetted flows from the inlet openings 14 of both side surfaces 10A, 10B into the respective fluid-supply holes 12A, 12B (see
The grinding fluid flows through the respective fluid-supply holes 12A, 12B to be jetted from the outlet openings 13 on the opposite sides to be supplied onto both side surface 20A, 20B and the outer peripheral surface 20D.
Another nozzle (not shown in the figures) also jets grinding fluid on the outer peripheral surface 20D of the grindstone member 20.
These grinding fluids cool both side surfaces 20A, 20B and the outer peripheral surface 20D of the grindstone member 20.
While both side surfaces 20A, 20B of the grindstone member 20 are kept in contact with the side surfaces 92a, 92a of both crank webs 92, 92, the outer periphery of the grinding wheel 1 is inserted between both crank webs 92, 92 to grind the side surfaces 92a, 92a of both crank webs 92, 92. The outer peripheral surface 20D of the grindstone member 20 comes in contact with the outer peripheral surface 91 a of the crank journal 91 to grind the outer peripheral surface 91a of the crank journal 91.
It is noted, as shown in
According to the above-described grinding wheel 1, as shown in
The grinding fluid, supplied onto both side surfaces 10A, 10B of the disc member 10, is blocked on the outer peripheral walls 11 and is guided to the inlet openings 14, 14 of the respective fluid-supply holes 12A, 12B. This guide enables the grinding fluid to securely flow into the respective fluid-supply holes 12A, 12B, which remarkably reduces a supply amount of the grinding fluid.
The respective fluid-supply holes 12A, 12B are formed in straight lines from the inlet openings 14 to the outlet openings 13 in radial directions of the disc member 10, and enable the grinding fluid to smoothly flow through respective fluid-supply holes 12A, 12B.
Though the above description is given of the first embodiment of the invention, the present invention is not limited to the first embodiment and is enabled to be properly modified without departing from the scope of the invention.
The number and the sizes of the first fluid-supply holes 12A and the second fluid-supply holes 12B as shown in
As shown in
Recessed grooves 21 of the grindstone member 20 as shown in
The number of the fluid-supply nozzles 30 is not limited. To enable the grinding fluid to sufficiently flow into the respective fluid-supply holes 12A, 12B, the number and arrangement of the fluid-supply nozzles 30 are set depending on the areas, the rotation speeds and the like of the side surfaces 10A, 10B of the grinding wheel 1.
The grinding wheel 2 of the second embodiment, as shown in
The grinding wheel 2 of the second embodiment, as shown in
The grinding wheel 2 of the second embodiment is used to grind the grind-object component W as shown in
The grinding fluid flows through the fluid-supply holes 12C to be jetted out of the outlet opening 13. Then, the grinding fluid is supplied onto the bottom surface 50A and both side surfaces 50B of the grindstone member 50. The bottom surface 50A on the grindstone member 50 comes in contact with the top surface W1 to grind the top surface W1.
According to the grinding wheel 2 of the above-described second embodiment, the grinding fluid is jetted to the vicinity of the grindstone member 50, and is enabled to be sufficiently supplied onto the bottom surface 50A of the grindstone member 50.
The grinding fluid, being supplied onto the top surface 10E of the disc member 10, is blocked on the outer peripheral wall 11 and is guided to the inlet openings 14 of the fluid-supply holes 12C. This guide enables the grinding fluid to securely flow into the respective fluid-supply holes 12C, which remarkably reduces a supply amount of the grinding fluid.
Number | Date | Country | Kind |
---|---|---|---|
2010-271118 | Dec 2010 | JP | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/JP2011/077523 | 11/29/2011 | WO | 00 | 6/6/2013 |