The present application claims priority under 35 U.S.C. .sctn.119 to Japanese Patent Application No. 2002-180009, filed on Jun. 20, 2002. The content of this application is incorporated herein by reference in its entirety.
1. Field of the Invention
The present invention relates to a grinding method of and a grinding machine for grinding a workpiece with a rotating grinding wheel wherein grinding fluid is reliably led to the grinding point.
2. Description of the Related Art
Conventionally, there have been used some kinds of grinding machines, for example as shown in
The inventors of the present invention found out that the air flow flows faster at axial end portions on the circumferential surface of the grinding wheel G than at the middle thereof. This is because air layers of flowing air on both lateral sides of the grinding wheel G are spirally and acceleratively drown in the rotational direction by its rotation from the rotational center to the circumferential surface and thus affect the air flows at the axial end portions of the circumferential surface. This makes the cause to partly obstruct leading the grinding fluid to the grinding point. Especially, where the peripheral velocity of the grinding wheel G is increased to high speeds such as 120 m/s or more for high grinding efficiency, or where the thickness of the grinding wheel G is thin, the foregoing drawback occurs remarkably. In these cases, it becomes hard to lead the grinding fluid to the grinding point reliably. In the second conventional grinding machine, the grinding fluid ejected from the nozzle 41 is able to cut off the air flow on the circumferential surface of the grinding wheel G and is put thereto to be led to the grinding point. However, since the air flows on both lateral sides of the grinding wheel G affect those at the axial end portions of the circumferential surface, the grinding fluid is hardly put on the circumferential surface and whereby it does not reach the grinding point. In the first conventional grinding machine, since the grinding fluid is pressurized for being led to the grinding point, there must be consumed much volume of the grinding fluid. Accordingly, there must be used a high pressure pump and a large tank for the grinding fluid, whereby the facility must be of high cost. In addition, the grinding fluid and electric power are increased in consumption which causes the maintenance cost to increase.
Accordingly, what is a primary object of the present invention is to provide a grinding method and a grinding machine in which a workpiece is ground with a grinding wheel while grinding fluid is led to the grinding point without being obstructed by the air flow rotating with grinding wheel.
According to the present invention, there is provided a grinding method or a grinding machine in which the grinding fluid is supplied toward the grinding point where the workpiece is ground with the grinding wheel and an air layer of flowing air on a lateral side of the grinding wheel is drawn its rotation. And a fluid jet is ejected across the air flow above the grinding point in the rotational direction of the grinding wheel. As a result, the air layer on the lateral side of the grinding wheel is turned not to head for the grinding point whereby the grinding fluid is reliably led the grinding point.
Preferably, a baffle plate is attached beside the lateral side of the grinding wheel with a little clearance. The baffle plate is disposed at a little above the fluid jet in the rotational direction of the grinding wheel and parallels the direction of the fluid jet. Thus, the air flow on the lateral side of the grinding wheel can be effectively cut off by the baffle plate.
Moreover, the baffle plate and fluid jet are directed along a hypothetical chord of an arc region, a part of the grinding wheel, including the grinding point. Therefore, the air flow toward the arc region can be cut off more effectively.
A further fluid jet is ejected across the circumferential surface of the grinding wheel above the grinding point. Therefore, the fluid jet cuts off an air layer following the circumferential surface so that the grinding fluid is more reliably led to the grinding point.
Various other objects, features and many of the attendant advantages of the present invention will be readily appreciated as the same becomes better understood by reference to the following detailed description of the preferred embodiment when considered in connection with the accompanying drawings, wherein the same reference numerals designated identical or corresponding parts throughout several views and in which:
A first embodiment of the present invention will be described with reference to
A guard 22 with a baffle plate 31 (referred to later) is fixed to the wheel head 11 to cover the grinding wheel G. Side nozzles 25a and 25b of a fluid jet supply system 24 are attached to the baffle plate 22, wherein the spouts of the side nozzles 25a and 25b oblique downwardly toward the forward part of both lateral sides 23a and 23b of the grinding wheel G for blowing air jets 29 thereto, respectively. A baffle device is composed of the baffle plate 31 and the fluid jet system 24. Both air jets 29 are blown to cutoff points 26 above the grinding point P in the rotational direction of the grinding wheel G, wherein the cutoff points 26 are on both lateral sides 23a and 23b close to the circumferential surface 23c. Therefrom, each air jet 29 flows along a hypothetical chord 28 of an arc region 27 including the grinding point P, wherein the arc region 27 is a part of the grinding wheel G close to the workpiece W. Each spout of the side nozzles 25a and 25b obliques a little in a rearward direction of the grinding machine in order to prevent the air jets 29 from reaching the grinding point P along the lateral sides 23a and 23b. Therefore, an air layer 30 flowing air along each lateral side 23a and 23b is turned to flow along the baffle plate 31 and is prevented from reaching the arc region 27, wherein the air layer 30 is spirally and acceleratively drawn by the rotating grinding wheel G from its rotational axis to its circumferential surface 23c. The ambient air can be used for the fluid jet supply system 24 to be supplied through the side nozzles 25a and 25b.
A little above than the cutoff point 26 in the rotational direction of the grinding wheel G, the baffle plate 31 is disposed in parallel with the hypothetical chord 28 of the arc region 27 and is attached to the guard 22 which is fixed to the wheel head 11. The baffle plate 31 has an opening 32 whose side portions 32a and 32b respectively face to the lateral sides 23a and 23b of the grinding wheel G with a little clearance, wherein each side portion 32a and 32b exists across a radial line that extends radially of the grinding wheel G to pass the grinding point P and the spindle 13. A bottom 32c of the opening 32 faces to the circumferential surface 23c of the grinding wheel G with a little clearance in order to substantially prevent the air layer 33 on the circumferential surface 23c from reaching the grinding point P. For constant clearance between the bottom 32c and circumferential surface 23c, the baffle plate 31 can be attached to the guard 22 through a compensation system which automatically compensate the position of the baffle plate 31 for the radial reduction of the grinding wheel G by dressing.
A grinding fluid nozzle 38 of a grinding fluid supply system 37 is attached to the guard 22 and ejects grinding fluid toward the workpiece W or grinding point P where the workpiece W is ground with the grinding wheel G.
The operation of the above grinding machine as constructed above will be described. The wheel head 11 advances upon rotation of the servomotor 12 and the workpiece W is ground with the grinding wheel G rotating at a high speed, for example 160 m/s of the peripheral velocity. In the case that the baffle plate 31 and side nozzles 25a and 25b are not, each air layer 30 of the flowing air following the lateral sides 23a and 23b spirally and acceleratively is drawn toward the circumferential surface 23c along the lateral sides 23a and 23b. Therefore, a part of each air layer 30 is added to the air layer 33 following the circumferential surface 23c and affects the same to cause those at the axial end portions to flow faster than at other portions. In this case, the air flow speed of the air layer 33 on the circumferential surface 23c was measured by the Pitot tube. As shown by the broken line 45 in
In the first embodiment, the baffle plate 31 and side nozzles 23a and 23b, whose operations will be described hereinafter, are provided for the grinding machine. At first, the side portions 32a and 32b of the opening 32 and its bottom 32c serve to substantially cut off the air layers 30 and 33 flowing along the lateral sides 23a and 23b of the grinding wheel G and its circumferential surface 23c, respectively. Next, each air jet 29 is obliquely blown toward each cutoff point 26 on the lateral sides 23a and 23b close to the circumferential surface 23c. This causes the air layers 30 flowing to turn downwardly thereby to flow along the chord 28 of the arc region 27. Therefore, the air layers 30 passing through the clearances between the baffle plate 31 and both lateral sides 23a and 23b are prevented from flowing into both arc regions 27. The substantial parts of the air layers 30 and 33 are cut off by means of the baffle plate 31, whereby the remaining parts of thereof are slowed down. Further, the remaining parts of the air layers 30 which pass through the clearances between the baffle plate 31 and both lateral sides 23a and 23b are hit by the air jets 29 to be turned downwardly. Owing to the air layers 30 and 33 weakened, the flowing air layer 33 following the circumferential surface 23c is remarkably slowed down in flowing speed around the grinding point P as shown by the solid line 46 in FIG. 4. This ensures that the grinding fluid from the grinding fluid nozzle 38 can be reliably led to the grinding point P.
Where the peripheral velocity of the grinding wheel G was set 120 to 160 m/s, 30 to 50 litters of the grinding fluid per minute was necessary in the prior art grinding machine. However, the amount of the supplied grinding fluid was able to be reduced to about 15 to 25 litters per minute in the first embodiment. In this case, since the air jets 29 downwardly flow along the hypothetical chord 28 in the same direction as the grinding wheel G moves at around the grinding point P as shown in
A second embodiment of the present invention will be described with reference to
In addition to the baffle device in the first embodiment, a further fluid jet supply system 34 is provided for blowing an air jet 36 from one lateral side 23a to the other side 23b across the air layer 33 following the circumferential surface 23c of the grinding wheel G. A crossing nozzle 35 of the further fluid jet supply system 34 is horizontally attached to the guard 22 to open toward the front edge of the circumferential surface 23c of the grinding wheel G between the grinding point P and its upstream cutoff point 26. Accordingly, the air jet 36 is horizontally blown onto the front edge of the circumferential surface 23c from one lateral side 23a to the other side 23b. To cope with the radial reduction of the grinding wheel G by the dressing, the crossing nozzle 35 takes the form of an ellipse which is elongated in the radial direction, whereby the air jet 36 can be blown onto the front edge of the circumferential surface 23c over the entire life of the grinding wheel G. The ambient air can be used for the further fluid jet supply system 34.
In the second embodiment, the crossing nozzle 35 is added to the first embodiment. The amount of the flowing air layer 33 following the grinding wheel G is reduced by the baffle plate 31 and air jets 29 blown from the side nozzles 25a and 25b. Additionally, the flowing air layer 33 which passed through the baffle plate 31 is turned or carried away by the air jet 36 which is ejected across the flowing direction of the air layer 33, since the air jet 36 is blown from the crossing nozzle 35 to the front edge of the circumferential surface 23c. Therefore, the flowing air layer 33 following the circumferential surface 23c can be slowed down around the grinding point P more effectively than that in the first embodiment as shown by the broken line 47 in FIG. 4. This advantageously makes the grinding fluid be more reliably led to the grinding point P from the grinding fluid nozzle 38 without being obstructed by the flowing air layers 30 and 33 following the rotating grinding wheel G.
The first and second embodiments described herein above can be utilized in practicing a face grinding and a surface grinding.
When the face grinding is practiced as shown in
Although in the above embodiments, the baffle plate 31 and nozzles 23a, 23b and 35 are applied to the grinding machine for the cylindrical and face grinding, they can be applied to a surface grinding machine as shown in
Obviously, numerous modifications and variations of the present invention are possible in light of the above teachings. It is therefore to be understood that within the scope of the appended claims, the present invention may be practiced otherwise than as specifically described herein.
Number | Date | Country | Kind |
---|---|---|---|
2002-180009 | Jun 2002 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
3628293 | Kobayashi et al. | Dec 1971 | A |
3834088 | Matson | Sep 1974 | A |
4619081 | Lipanski | Oct 1986 | A |
6305183 | Mukai et al. | Oct 2001 | B1 |
20040005844 | Morita et al. | Jan 2004 | A1 |
Number | Date | Country |
---|---|---|
1 339 254 | Oct 1963 | FR |
2 752 182 | Feb 1998 | FR |
361241065 | Nov 1986 | JP |
Number | Date | Country | |
---|---|---|---|
20030236059 A1 | Dec 2003 | US |