VIBRATION STABILIZING GUIDE WHEEL

Abstract

A fixed guide wheel that when coupled to a saw blade or a grinding wheel provides a sawing or grinding system that will control the exact depth at which the tools are allowed to perform. The guide wheel also rolls along the top surface of the work piece pushing down on it (pinching it) while the cutting or grinding process is occurring. The guide wheel has a central bearing that carries the saw blade or grinding wheel across the surface of the stone keeping the tools centered and balanced with each other. The guide wheel is made from a rigid, low-density material that absorbs vibration that would normally transfer from the grinding wheel to the material being cut.

Description

CROSS-REFERENCE TO RELATED APPLICATIONS

Not applicable.

BACKGROUND

1. Field of Invention

This invention is a guide wheel that allows consistent vibration free grinding when used with electroplated diamond grinding wheels; segmented diamond grinding wheels and diamond rimmed saw blades.

2. Description of Prior Art

For years, the industry has been using diamond tools to cut and fabricate ceramic tile and natural stone products. These tools are typically used with a portable tile saw that can easily be set up and used on location. All tile saws with a standard arbor size can use a profile wheel to create different profiles or shapes on the edge of the material being installed. The profile wheels are made in several different shapes and sizes. Since the introduction of profile wheels, people have come to realize that even though it is a good idea, their capabilities are extremely limited. The first problem is that all portable tile saws share the same basic design. They have a welded square tube frame that has a support post located in the back left side of the machine. This support post holds the upper saw assembly in place while the machine is operating. When a saw blade or a profile wheel is being used, the entire upper saw assembly would rise up slightly upon contact with the material and then go down as material is removed. This movement carries the profile wheel up and down creating a rough, inconsistent edge. If it does not grind enough, the material needs to be further worked. In either case, the machine is constantly moving up and down creating an impossible situation for precision grinding.

The second problem is stone tiles will vary in thickness from one box to another throughout the job. Individual tiles can actually taper in thickness.

The third problem is that natural stone has inconsistencies in material hardness. This allows the profile wheel to remove more material in a soft area and rise up and over a harder one. Even small pieces of debris under a tile being profiled can cause over grind situations. This forces the installer to cut that particular tile into a smaller size to be used elsewhere on the job. It should be appreciated that every natural stone tile is unique and if one is damaged due to over grinding, it cannot be readily replaced.

When a saw blade is being used under these up and down conditions, it causes excessive chipping along the top edge of the tile. This larger or deeper chipping forces the fabricator to grind and polish a deeper bevel on the tile's edge. This ultimately affects the width of the grout line, especially if tiles are being installed very close together. This process is called “little or no grout” installation.

Working with stone is a very slow process. Most material is so hard, only diamonds can be used to remove the material with consistent accuracy. The initial cut or profile grind must be accurate because the polishing process that follows wan not designed to remove material readily. The polishing process was designed to remove surface scratches and bring the stone to a final polish.

SUMMARY

The invention is a guide wheel that is preferably machined from acetate (delrin) and can be used with any diamond grinding wheel or diamond saw blade. When using the guide wheel with a grinding wheel, the size of the guide wheel is determined by the exact point at which the grinding wheel's shape should stop grinding. This eliminates the possibility of over grinding and creates a point from where all shapes can be consistently duplicated. When using the guide wheel with a diamond rimmed saw blade, the size of the guide wheel is determined by two things; the diameter of the saw blade and the thickness of the material being cut. An eight-inch saw blade with a seven-inch guide wheel will have half of an inch of cutting depth. The guide wheel has an alignment groove located on its outside edge. This groove is used by the operator to quickly set the grinding wheel slightly below the top surface of the stone. The guide wheel has a center cavity that holds a heavy-duty roller bearing with two rubber seals. A stainless steel threaded insert is pressed into the center of the bearing. This insert replaces the tile saw's standard arbor nut. When tightened, the threaded insert now holds the profile wheel or the saw blade into place. Now, with the machine on, the center bearing can turn and the guide wheel does not turn due to a small amount of friction applied between the face of the guide wheel and the flat inside surface of the tile saw's blade guard assembly. The friction is controlled by simply adjusting the wing nut that was used to mount the blade guard to the tile saw.

DESCRIPTION

FIG. 2 is a cross section of a fully assembled guide wheel. Stainless steel threaded insert (13) is press fit into bearing (12). Threaded insert (13) extends through bearing (12) ⅛^th of an inch and lock ring (11) is press fit onto end of threaded insert (13). Once this is done, entire assembly press fits into center cavity of guide wheel (10). Then, internal snap ring (14) is installed. Note: Bearing (12) must make contact with guide wheel beating seat (19) to ensure proper clearance for snap ring (14).

FIG. 4 shows an adjustable wing nut (27) connected to mount bolt (30). This bolt assembly connects the blade guard (26) to the tile saw that is being used.

FIG. 4 shows blade guard contact area (16) making contact with the inside of the tile saw blade guard (26). FIG. 4 shows clearance (23) between inside of blade guard (26) and the face of threaded insert (13). FIG. 4 shows alignment groove (15) making contact with the top outside corner of tile material (25). FIG. 3 shows guide wheels tile contact surface area (17) making full contact with the tile material (25). FIG. 3 shows zero point (30). FIG. 3 shows profile wheel clearance (24) and clearance (20).

Note:

Clearance 20 0.035-0.040

Clearance 24 0.0125-0.130

Alignment groove 15 0.125×0.125

Description of Stainless Steel Threaded Insert (13)

FIG. 1—Threaded insert (13) has internal threads (18) that are tapped through. Internal threads (18) are the same size as the tile saw arbor nut. Shoulder flange (22) seats up against bearing (12) to ensure proper alignment. Wrench flats (22) are machined into face of threaded insert (13).

FIG. 2—Shows necessary clearance (23) between threaded insert (13) and blade guard contact area (16).

REFERENCE NUMERALS IN DRAWINGS
Guide wheel                      10
Lock ring                        11
Bearing                          12
Stainless steel threaded insert  13
Stainless steel internal snap ring 14
Alignment groove                 15
Blade guard contact area         16
Guide wheels tile contact surface 17
Internal threads thru            18
Guide wheel bearing seat         19
Clearance area .035-.040         20
Wrench flats                     21
Shoulder flange                  22
Clearance                        23
Profile wheel clearance          24
Tile material                    25
Blade guard                      26
Wing nut                         27
Waterfeed tubes                  28
Profile wheel                    29
Mount bolt                       30
Saw blade                        31
Blade shaft                      32
Extension arm                    33

OPERATION

In operation, one could install the system on a standard portable tile saw. First, remove the wing nut (27) and the mount bolt (30) in FIG. 4. Then the blade guard (26) can be removed and set aside. If necessary, remove stock arbor nut, blade flange and saw blade from machine and set aside. Install the profile wheel (29) as seen in FIG. 3 onto the machine shaft and thread on the guide wheel (10) until it tightens up against the profile wheel (29) in FIG. 3. Reinstall blade guard assembly (26) in FIG. 4 and mount bolt (30) and wing nut (27) in FIG. 4. Adjust wing nut (27) until inside of blade guard (26) applies enough force to keep the guide wheel (10) from turning easily. Do not over tighten as this will lock up the guide wheel (10) and cause it to slide across tile material (25). The guide wheel (10) is designed to roll across tile material (25) when in use but the guide wheel (10) should not turn unless there is tile material (25) under it forcing it to turn. Next, adjust the machine down into position until the alignment groove (15) fits into the top corner of tile material (25) in FIG. 4. Tighten all adjustments so that the machine cannot move from this position. Guide wheel (10) and the profile wheel are now adjusted ⅛^th inch below the top surface of the tile material (25) in FIG. 4.

Move the tile material (25) into position for profiling as in FIG. 3. Turn on the tile saw and check the guide wheel (10) FIG. 4 and make sure that guide wheel (10) is not turning. If it is, turn off the machine and tighten wing nut (27) in FIG. 4 until the inside of the blade guard (26) is applying enough friction against the face of the guide wheel (10) to keep it from turning when the machine is operating. By adjusting profile wheel (29) and guide wheel (10) slightly below the surface of tile material (25) in FIG. 4, we create a situation where the tile saw will go ahead and raise up when it contacts tile material (25) in FIG. 3. Because the guide wheel (10) allows us to lock in the grinding height well below the tip surface of tile material (25), we can take advantage of a downward force created when the tile material (25) is rolled under the grinding wheel. This downward energy forces the profile wheel (29) to quickly remove the unwanted material faster with less passes. Guide wheel (10) is also applying a downward force on the edge of tile material (25). This downward force keeps the edge of tile material (25) from vibrating during the grinding process. While all of this is happening, the Delrin or acetate guide wheel (25) is absorbing vibration created by the grinding or sawing process. The acetate also protects the tile material (25) surface from scratches if the blade guard assembly is adjusted too tight (which causes the guide wheel to lock up and slide across the surface of the stone).

Note: When using a profile wheel (29) to remove material as seen in FIG. 3, the profile wheel (29) applies a force that wants to push tile material (25) out of position. For this reason, I designed an extension arm (23) in FIG. 5.

A fixed wheel that stabilizes and absorbs vibration and controls depth of cut when coupled to a saw blade or grinding wheel comprising:

• • (a) fixed wheel of pre-determined size preferably made from a rigid low density self lubricating material
  • (b) a bearing centrally mounted in said fixed wheel which will able said fixed wheel to slowly rotate or be held stationary regardless of said central bearings internal speed of rotation
  • (c) said central bearings internal bore with a fastener provides means to couple said fixed wheel to any saw blade or grinding wheel
  • (d) said fixed wheel with a said pre-determined diameter coupled to said saw blade or said grinding wheel with a said pre-determined diameter creates an exact contact point between said fixed wheel diameter and the optimal depth of cut of said saw blade or said grinding wheel
  • (e) position said fixed wheel coupled to said grinding wheel in a vertical
  • (f) providing a flat piece of hard rigid material and placing it onto a carriage that will carry said material directly under and in line with said coupled fixed wheel grinding wheel
  • (g) position said fixed wheel's diameter slightly below said material's surface height and lock said coupled fixed wheel grinding wheel into place whereby as said material passes under and through said coupled fixed wheel grinding wheel said fixed wheel pushes down on said material holding said material as said fixed wheel rolls across flat surface of said material said fixed wheel's central bearing centers said grinding wheel's rotation while said fixed wheel's low density material absorbs rotation.

Claims

1. A method comprising:

for a profile wheel fixedly mounted to a shaft and a guide wheel rotatably mounted to the shaft, the guide wheel having a face and a contact surface, applying a first friction to the face of the guide wheel through a first force, the first friction sufficient to prevent the guide wheel from turning when the shaft is turning and without the contact surface of the guide wheel contacting a first surface; and

while still applying the first friction, applying a second force through the shaft to the guide wheel toward the first surface to force the guide wheel to rotate as the guide wheel is moved across the first surface as the contact surface of the guide wheel is contacting the first surface.

2. The method of claim 1 wherein the second force is applied through the shaft by first, positioning the shaft in a first position when the contact surface of the guide wheel is free from contacting the first surface and by second, moving the first surface to contact a portion of the contact surface of the guide wheel to move the shaft from the first position to a second position and to cause the second force to be applied to the shaft.

3. The method of claim 2 wherein the first position of the shaft is below the first surface and the second position of the shaft is above the first surface.

4. The method of claim 2 wherein a portion of the guide wheel other than the contact surface of the guide wheel contacts the first surface when the shaft is positioned in the first position.

5. The method of claim 1 wherein the first friction is applied by contact with an acetate material.

6. The method of claim 1 wherein the first friction is applied by contact with a Delrin material.

7. The method of claim 1 wherein the first friction is applied by contact of a blade guard on to the face of the guide wheel.

8. A method comprising:

for a profile wheel fixedly mounted to a shaft and a guide wheel rotatably mounted to the shaft, the guide wheel having a face and a contact surface, applying a second force through the shaft to the guide wheel toward a first surface; and

decreasing a first friction to the face of the guide wheel through decreasing a first force until the first friction is sufficiently small to allow the guide wheel to rotate as the guide wheel is moved across the first surface as the contact surface of the guide wheel is contacting the first surface.

9. The method of claim 8 wherein the second force is applied through the shaft by first, positioning the shaft in a first position when the contact surface of the guide wheel is free from contacting the first surface and by second, moving the first surface to contact a portion of the contact surface of the guide wheel to move the shaft from the first position to a second position and to cause the second force to be applied to the shaft.

10. The method of claim 9 wherein the first position of the shaft is below the first surface and the second position of the shaft is above the first surface.

11. The method of claim 9 wherein a portion of the guide wheel other than the contact surface of the guide wheel contacts the first surface when the shaft is positioned in the first position.

12. The method of claim 8 wherein the first friction is applied by contact with an acetate material.

13. The method of claim 8 wherein the first friction is applied by contact with a Delrin material.

14. The method of claim 8 wherein the first friction is applied by contact of a blade guard on to the face of the guide wheel.

15. A system comprising:

for a profile wheel fixedly mounted to a shaft and a guide wheel rotatably mounted to the shaft, the guide wheel having a face and a contact surface, means for applying a first friction to the face of the guide wheel through a first force, the first friction sufficient to prevent the guide wheel from turning when the shaft is turning and without the contact surface of the guide wheel contacting a first surface; and

while still applying the first friction, means for applying a second force through the shaft to the guide wheel toward the first surface to force the guide wheel to rotate as the guide wheel is moved across the first surface as the contact surface of the guide wheel is contacting the first surface.

16. The system of claim 15 wherein the second force is applied through the shaft by first, means for positioning the shaft in a first position when the contact surface of the guide wheel is free from contacting the first surface and by second, means for moving the first surface to contact a portion of the contact surface of the guide wheel to move the shaft from the first position to a second position and to cause the second force to be applied to the shaft.

17. The system of claim 16 including means for the first position of the shaft to be below the first surface and means for the second position of the shaft to be above the first surface.

18. The system of claim 16 including means for a portion of the guide wheel other than the contact surface of the guide wheel to contact the first surface when the shaft is positioned in the first position.

19. The system of claim 15 including means for applying the first friction with an acetate material.

20. The system of claim 15 including means for applying the first friction with a Delrin material.

21. The system of claim 15 including means for applying the first friction.

22. A system comprising:

for a profile wheel fixedly mounted to a shaft and a guide wheel rotatably mounted to the shaft, the guide wheel having a face and a contact surface, means for applying a second force through the shaft to the guide wheel toward a first surface; and

means for decreasing a first friction to the face of the guide wheel through decreasing a first force until the first friction is sufficiently small to allow the guide wheel to rotate as the guide wheel is moved across the first surface as the contact surface of the guide wheel is contacting the first surface.

23. The system of claim 22 wherein the second force is applied through the shaft by first, means for positioning the shaft in a first position when the contact surface of the guide wheel is free from contacting the first surface and by second, means for moving the first surface to contact a portion of the contact surface of the guide wheel to move the shaft from the first position to a second position and to cause the second force to be applied to the shaft.

24. The system of claim 23 including means for the first position of the shaft to be below the first surface and means for the second position of the shaft to be above the first surface.

25. The system of claim 23 including means for a portion of the guide wheel other than the contact surface of the guide wheel to contact the first surface when the shaft is positioned in the first position.

26. The system of claim 22 including means for applying the first friction with an acetate material.

27. The method of claim 22 including means for applying the first friction with a Delrin material.

28. The method of claim 22 including means for applying the first frictionl.