A method for distributing a coolant to a grinding site of a grinding wheel, including rotating the grinding wheel, injecting the coolant in an inlet of the grinding wheel disposed proximate to an axis of rotation of the grinding wheel, moving the coolant fluid from the inlet along a plurality of int
A method for distributing a coolant to a grinding site of a grinding wheel, including rotating the grinding wheel, injecting the coolant in an inlet of the grinding wheel disposed proximate to an axis of rotation of the grinding wheel, moving the coolant fluid from the inlet along a plurality of internal grooves of the grinding wheel outwardly towards a plurality of outlets, and expelling the coolant outwardly from the plurality of outlets at an angle of at most 15 degrees with respect to a tangent to a circumference of the grinding wheel at the outlet.
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1. A method for distributing a coolant to a grinding site of a grinding wheel, the method comprising: rotating the grinding wheel;injecting the coolant in an inlet of the grinding wheel, the inlet being disposed proximate to an axis of rotation of the grinding wheel;moving the coolant fluid from the
1. A method for distributing a coolant to a grinding site of a grinding wheel, the method comprising: rotating the grinding wheel;injecting the coolant in an inlet of the grinding wheel, the inlet being disposed proximate to an axis of rotation of the grinding wheel;moving the coolant fluid from the inlet along a plurality of internal grooves of the grinding wheel outwardly towards a plurality of outlets; andexpelling the coolant outwardly from the plurality of outlets at an absolute coolant velocity, the absolute coolant velocity oriented at an angle of at most 15 degrees with respect to a tangent to a circumference of the grinding wheel at the outlet. 2. The method as defined in claim 1, wherein expelling the coolant outwardly from the plurality of outlets is performed with the angle with respect to the tangent to the circumference of the grinding wheel being at most 10 degrees. 3. The method as defined in claim 1, wherein expelling the coolant outwardly from the plurality of outlets is performed with the angle with respect to the tangent to the circumference of the grinding wheel being at most 5 degrees. 4. The method as defined in claim 1, wherein expelling the coolant outwardly from the plurality of outlets includes expelling the coolant with an absolute tangential speed at in a range of between 90 and 100% of a tangential velocity of the grinding wheel. 5. The method as defined in claim 1, further comprising: determining an angular shift of the coolant from a rotational speed of the grinding wheel and a time taken by the coolant to flow through the plurality of grooves to the outlets;determining a location of contact between the grinding wheel and a workpiece; andinjecting the coolant in the inlet is performed along only a portion of a circumference of the grinding wheel, the portion being circumferentially offset from the location of contact by the angular shift. 6. The method as defined in claim 1, wherein moving the coolant fluid from the inlet along the plurality of internal grooves is performed in each of the grooves along a curved shape, the coolant fluid moving from a respective groove inlet to a respective one of the outlets being circumferentially offset from the respective groove inlet in a direction opposite the direction of rotation of the wheel. 7. The method as defined in claim 1, comprising moving the coolant from the inlet of the grinding wheel along an annular passage of the grinding wheel before moving the coolant fluid along the plurality of internal grooves. 8. The method as defined in claim 1, wherein injecting the coolant in the inlet of the grinding wheel is performed through a coolant nozzle extending around a rotatable support member connected to the grinding wheel. 9. The method as defined in claim 8, wherein the coolant flows through the coolant nozzle around only part of a circumference of the support member. 10. A method for distributing a coolant to a grinding site of a grinding wheel, the method comprising: rotating the grinding wheel;injecting the coolant in an inlet of the grinding wheel, the inlet being disposed proximate to an axis of rotation of the grinding wheel;moving the coolant fluid from the inlet along a plurality of internal grooves of the grinding wheel outwardly towards a plurality of outlets; andexpelling the coolant outwardly from the plurality of outlets at an angle of at most 15 degrees with respect to a tangent to a circumference of the grinding wheel at the outlet;wherein each of the internal grooves is defined between first and second walls with the first wall being located in front of the second wall with respect to a direction of rotation of the wheel, and wherein an angle between the second wall adjacent a respective one of the outlets and the tangent to the outer circumference adjacent the respective one of the outlets is defined as: arctan(60Qtan(a2)2πR2A2Ntan(a2)-60Q)where Q is a flow rate of the coolant through the grinding wheel,N is a predetermined rotational speed of the grinding wheel in min−1,R2 is the radius of the outer circumference,A2 is a combined surface area of the plurality of outlets, andα2 is the angle of the coolant expelled outwardly from the plurality of outlets with respect to the tangent to the circumference of the grinding wheel at the outlet. 11. The method as defined in claim 10, wherein the angle between the second wall adjacent the respective one of the outlets and the tangent to the outer circumference adjacent the respective one of the outlets is also defined as arctan(QA2U2-nU2)where U2 is a tangential speed of the grinding wheel, and n is at least 0.9 and less than 1. 12. The method as defined in claim 10, wherein a combined surface area of the inlets of the grooves is greater than the combined surface area of the plurality of outlets A2. 13. The method as defined in claim 10, wherein expelling the coolant outwardly from the plurality of outlets is performed with the angle with respect to the tangent to the circumference of the grinding wheel being at most 10 degrees. 14. The method as defined in claim 10, wherein expelling the coolant outwardly from the plurality of outlets is performed with the angle with respect to the tangent to the circumference of the grinding wheel being at most 5 degrees. 15. The method as defined in claim 10, wherein expelling the coolant outwardly from the plurality of outlets includes expelling the coolant with an absolute tangential speed at in a range of between 90 and 100% of a tangential velocity of the grinding wheel. 16. The method as defined in claim 10, further comprising: determining an angular shift of the coolant from a rotational speed of the grinding wheel and a time taken by the coolant to flow through the plurality of grooves to the outlets;determining a location of contact between the grinding wheel and a workpiece; andinjecting the coolant in the inlet is performed along only a portion of a circumference of the grinding wheel, the portion being circumferentially offset from the location of contact by the angular shift. 17. The method as defined in claim 10, wherein moving the coolant fluid from the inlet along the plurality of internal grooves is performed in each of the grooves along a curved shape, the coolant fluid moving from a respective groove inlet to a respective one of the outlets being circumferentially offset from the respective groove inlet in a direction opposite the direction of rotation of the wheel. 18. The method as defined in claim 10, comprising moving the coolant from the inlet of the grinding wheel along an annular passage of the grinding wheel before moving the coolant fluid along the plurality of internal grooves. 19. The method as defined in claim 10, wherein injecting the coolant in the inlet of the grinding wheel is performed through a coolant nozzle extending around a rotatable support member connected to the grinding wheel. 20. The method as defined in claim 19, wherein the coolant flows through the coolant nozzle around only part of a circumference of the support member.
Schwartz, Brian J.; Davie, Jr., Robert N.; Vaillette, Bernard D.; Hammett, Jon C.; Packman, Allan B.; Brown, Timothy L.; Campbell, Jr., James D., Coolant nozzle.
Smart William L. (Indianapolis IN) Hoenig Stuart A. (Tucson AZ) Savitz Christian W. (Tucson AZ) Darlington Douglas K. (Tucson AZ), Grinder apparatus with pollution control fluid dispensing means.
Shoenhair John J. (New Hope MN) Kallevig Bruce E. (Monticello MN), Method and apparatus for limiting the dispersion of rail grinding machine spark and dust residue.
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