This invention relates generally to means and methods for cutting stone and relates, more particularly, to such means and methods for cutting a stone sheet, such a granite or marble sheet.
The class of stone cutting systems with which this invention is to be compared includes those which are used to shape or cut a stone sheet. A stone sheet, comprised, for example, of granite, can be cut or formed with such a cutting system for use, for example, as a kitchen countertop. Since a kitchen countertop commonly requires that an opening be cut out of the countertop material for acceptance of a sink installed therein, these cutting systems should possess the capacity to cut or form a sink-accepting cutout in a stone sheet.
Stone-cutting systems of the prior art are commonly complicated in construction, expensive to purchase and are time-consuming to use. It would therefore be desirable to provide an improved cutting system which is relatively inexpensive to construct and can be used to cut a sink-accepting opening in stone relatively quickly.
Accordingly, it is an object of the present invention to provide a new and improved stone cutting system and a method of use.
Another object of the present invention is to provide such a system which is relatively inexpensive to construct and relatively easy to use.
Still another object of the present invention is to provide such a system which employs a cutting tool which is supported for movement across the surface of a stone sheet while the tool is maintained in cutting engagement with the stone sheet.
Yet another object of the present invention is to provide such a system wherein the cutting tool of the system can be manually guided across the surface of the stone sheet.
A further object of the present invention is to provide such a system wherein the cutting tool is movable into and out of the stone sheet to accommodate an adjustment in the depth of cut in the stone sheet.
A still further object of the present invention is to provide such a system which is capable of forming a cutout in a stone sheet relatively quickly.
A yet further object of the present invention is to provide such a system which is uncomplicated in structure, yet effective in operation.
This invention resides in a system and method for cutting a stone sheet having a substantially planar surface.
The stone cutting system includes a frame upon which a stone sheet to be cut can be positioned so that a substantially planar surface of the stone sheet extends along X and Y coordinate axes. Means are also included for supporting a cutting tool for rotation about a Z-coordinate axis and for rotating the cutting tool about the Z-coordinate axis. Further still, means are joined between the frame and the tool-supporting means for supporting the tool-supporting means for movement along either of the X and Y coordinate directions to enable the cutting tool to be positioned at any of a number of X and Y coordinate locations across the substantially planar surface of the stone sheet. Means are also included for moving the cutting tool along the Z-coordinate axis toward and into engagement with the substantially planar surface of the stone sheet so that by rotating the cutting tool about the Z-coordinate axis and moving the cutting tool in cutting engagement with the stone sheet along X or Y coordinate directions, a cut is effected in the stone sheet by the cutting tool.
The method of the invention includes the steps involved to utilize the system of the present invention. Such steps include the steps of placing a stone sheet to be cut upon the frame of the system so that the substantially planar surface of the stone sheet extends along X and Y coordinate axes, and then arranging the cutting tool adjacent the substantially planar surface of the stone sheet. The cutting tool is subsequently rotated about the Z-coordinate axis and moved along the Z-coordinate direction toward and into engagement with the substantially planar surface of the stone sheet. The cutting tool is thereafter moved in cutting engagement with the stone sheet along X or Y coordinate directions to effect a cut in the stone sheet.
If desired, a template having an edge along which the cutting tool can be guided can be positioned against the substantially planar surface of the stone sheet prior to the step of moving the cutting tool in cutting engagement with the stone sheet.
Turning now to the drawings in greater detail and considering first
As best shown in
With reference to
By way of example, the support surface 24 of the frame 22 can be constructed to measure about eight feet long and about twenty-seven inches wide. Furthermore, the length of the legs 36 can be sized to provide the support surface 24 with a height of about thirty-eight inches, although the support surface 24 can be provided with an alternative height for conveniently working on a stone piece 26 positioned thereon.
If desired, the frame 22 can be overlain with an intermediate layer of materials, such as wooden boards 39 (
With reference again to
The cutting tool 30 also includes a shank portion 44 adapted to be accepted by and firmly secured within a standard tool holder 46 associated with the cutting head 29 so that when secured within the tool holder 46, the tool 32 depends downwardly therefrom and is thereby connected in driven relationship with the motor 32. Within the depicted system 20, the motor 32 is supported so that the axis of rotation of the cutting tool 30 is oriented along the vertical (i.e. the indicated Z-coordinate axis). Therefore and as will be apparent herein, by rotating the cutting tool 30 along the Z-coordinate axis and moving the cutting body 42 of the tool 30 along an X-Y coordinate path while in cutting engagement with the stone piece 26, the tool head 42 removes material from the stone piece 26 so that the width of the cut, or kerf, formed by the tool 30 corresponds with the width of the cutting body 42. A cutting tool which is suitable for use as the tool 30 are known as a radial arm finger bit and is available from VIC International, Inc. of Powell, Tenn.
Within the cutting head 29, the motor 32 is encased within a housing 48, and the housing 48 is, in turn, is supported by the articulated arm assembly 34 in a manner which permits the motor 32 and the tool 30 which depends downwardly therefrom to be moved to any X and Y coordinate location upon the upper surface 35 of the stone piece 26 and which permits the motor 32 and tool 30 to be moved along the Z-axis so that the tool 30 can be positioned at any of various depths within the stone piece 26 for removal of material therefrom. The motor 32 is electrically-powered and adapted to receive power from an electrical power source (not shown) and can be turned ON and OFF with a switch 50. An example of a motor suitable for use as the motor 32 is a three-phase, 415/240 volt motor capable of rotating at about 10,000 rpm and is available from Venetia Elettro Maccanica of Italy. If such an exemplary motor is used as the motor 32 and a user of the system 20 only has access to a single-phase, 220 volt power supply, then an inverter, indicated 136 in
Within the depicted system 20 and with reference to
One of, or a first, arm member 54 has two opposite ends 58, 60, while the other, or second, arm member 56 has two opposite ends 62, 64. The end 58 of the first arm member 54 is pivotally joined to the frame 22 to permit pivotal movement of the first arm member 58 relative to the frame 22 about a first (and vertical) axis of pivot, indicated 66. Meanwhile, the ends 60 and 62 of the first and second arm members 54 and 56 are pivotally joined together to accommodate pivotal movement of the arm members 54 and 56 relative to one another about a second (and vertical) axis of pivot, indicated 68. The end 68 of the second arm member 56 is attached, in a manner described herein, to the cutting head 29 so that the cutting head 29 is supported in a cantilevered fashion by the arm assembly 34 above the support frame 22.
For purposes of joining the assembly 34 of arm members 54, 56 to the frame 22 and for supporting the arm assembly 34 above the support surface 24 of the frame 22, the frame 22 includes a vertically-oriented support post 70 which is arranged adjacent the leg 36 (
For securement of the first arm member 54 (
In this connection, the second arm member 56 includes an outer sleeve portion 82 at the end 62 thereof and which is positioned about the post portion 76, and there is provided a pair of spaced-apart wheel (e.g. ball) bearings 84 which are interposed between the inner surface of the outer sleeve portion 82 and the outer surface of the post portion 76 to accommodate the pivotal movement of the second arm member 56 relative to the first arm member 54 about the second vertically-disposed axis 68. If desired, a collar 86 can be positioned about the post portion 76 and directly beneath the outer sleeve portion 82 for supporting the weight of the second arm member 56.
It follows that by pivotally moving the second arm member 56 relative to the first arm member 54 about the second vertical axis 68 and by moving the second arm member 56 relative to the frame 22 about the vertical axis 66, the end 64 of the second arm member 56 can be positioned over any X-Y coordinate position across the support surface 24 of the frame 22 and therefore, over any X-Y coordinate position across the upper surface 35 of a stone piece 26 positioned upon the support surface 24 of the frame 22. It also follows that the cutting head 29 (and the cutting tool 30 supported thereby) which is connected to the end 64 of the second arm member 56 can be positioned above any X-Y coordinate position across the upper surface 35 of a stone piece 26 positioned upon the frame support surface 24.
It is a feature of the system 20 that the bearings in each set of bearings 74 and 84 are spaced apart (by, for example about 9.0 to 11.0 inches) along the corresponding post 70 or post portion 76 about which the bearings are positioned. Such a spacing is believed to provide sufficient strength to resist appreciable deformation or bending of the arm assembly 34 as the result of upwardly or downwardly-directed forces which may be applied at the cutting head 29. This advantage can be appreciated when considering the appreciable weight of the cutting head 29 which is expected to be supported by the arm assembly 34 between cutting operations.
To enable the cutting head 29 and the tool 30 to be moved along the indicated Z-coordinate axis (and thus toward and away from the upper surface 35 of the stone piece 26 and with reference to
For purposes of moving the cutting head 29 and cutting tool 30 upwardly and downwardly along the guide track member 92, there is fixedly joined to the cutting head 29 a bracket 98 having a flange 100 which is positioned above the end 64 of the second arm member 56, and a jackscrew assembly 102 is interposed between the arm member 56 and the flange 100 enabling the flange 100 and arm member 56 to be moved toward or away from one another by a user. The jackscrew assembly 102 includes a vertically-arranged threaded rod 104 which is journaled at its lower end to the upper surface of the arm member 56 and extends upwardly from the arm member 56 through the bracket flange 100. A rotatable crank 106 is journaled to the flange 100 for rotation about a horizontal rotation axis and is connected, through a suitable gear assembly 108, to the threads provided along the rod 104 so that by rotating the crank 106 in one rotational direction or another about its rotation axis, the rod 104 is moved upwardly or downwardly relative to the arm member end 64 so that the bracket flange 100, and hence the cutting head 29 and cutting tool 30, are moved upwardly and downwardly relative to the frame 22 between, for example, the position illustrated in solid lines in
It follows that if a user of the system 20 desires to raise or lower the cutting tool 30 relative to a stone piece 26 positioned upon the frame support surface 24 and thereby adjust the depth-of-cut of the cutting tool 30 in the stone piece 26, the user rotates the crank 106 in an appropriate rotational direction about its rotation axis. More specifically, the rotation of the crank 106 in one rotational direction about its rotation axis effects a lowering of the cutting tool 30 relative to the support surface 24 of the frame 22 by a corresponding amount while the rotation of the crank 106 in the opposite rotational direction about its rotation axis effects a raising of the cutting tool 30 relative to the frame support surface 24 by a corresponding amount. Within the depicted system 20, one rotation of the crank 106 effects a corresponding movement of the cutting tool 30 along the Z-axis by about 1/20th of an inch (i.e. about 0.05 inches in depth).
With reference again to
The system 20 also includes means, generally indicated 112 in
To use the system 20 to form a cutout in a piece 26 of stone sheet and with reference to
The template 122 can be a planar sheet having a pre-formed hole 124 cut therein whose dimensions correspond with those of the cutout (e.g. that traced by the path 126) desired to be formed in the stone piece 26. The material of the template 122 can be comprised, for example, of a high density plastic material which is not easily cut by the cutting tool 30 when, and if, the rotating tool 30 comes into contact with the material of the template 122. Consequently, the cutting tool 30 can be positioned within the preformed hole 124 and manually guided along the inside edges of the hole 124 while contacting the stone piece 26 so that material of the stone piece 26 is removed by the cutting tool 30. Therefore and by guiding the cutting tool 30 along the entire edge of the preformed hole 124, the stone piece 26 is cut along its desired path.
With the template 122 in position over the stone sheet 26, the cutting tool 30 is positioned above a desired X-Y coordinate location along the path of the desired cut (e.g. that traced by the path 126), and the motor 32 is switched ON so that the cutting tool 30 begins to rotate about the Z-axis. The cutting tool 30 is then lowered (by way of the crank 106 and associated jackscrew assembly 102) until the lower end of the cutting tool 30 engages and cuts into the stone sheet 26.
The cutting tool 30 is not lowered very deeply (e.g. only by about 1/20th of an inch) into the material of the stone sheet 26 before the tool 30 is moved (i.e. guided) along the desired cutting path (i.e. along the inside edge of the preformed hole 124 of the template 122) as the user's hands are gripped about the ring 132 of the grip 130. As the tool 30 is moved along the desired cutting path, material is removed from the stone sheet 26 to effect a cut therein. Upon completion of one pass of the cutting tool 30 along the desired cutting path (e.g. that traced by the path 126), the tool is again lowered by a small amount (e.g. about 1/20th of an inch) and then the cutting tool 30 is again passed along the length of the cutting path. The steps of passing the tool 30 along the entire length of the cutting path and then lowering the tool 30 by a small amount are repeated until the area of material bordered by the desired path (e.g. the path 126) is completely severed from the remainder of the stone sheet 26.
It follows that a system and method have been described for cutting a stone sheet wherein the system 20 is comprised of a relatively few number of component parts and can be used relatively easily. Furthermore, the articulated arm assembly 34 of the system 20 enables a user to readily position the cutting tool 30 at a desired X-Y coordinate location across the planar surface 35 of the stone sheet 26 for working upon the stone piece 26 at that desired X and Y coordinate location. Once positioned at the desired X and Y coordinate location across the stone piece 26, the tool 30 is lowered into engagement with the stone sheet 26 for subsequent movement of the cutting tool 26 along a desired cutting path while the cutting tool 30 remains in cutting engagement with the stone sheet 26. By removing material from the stone sheet 26 with the cutting tool 30, the cutting tool 30 cuts the stone sheet 26.
It will be understood that numerous modifications and substitutions can be had to the aforedescribed embodiment 20 without departing from the spirit of the invention. For example, although the cooling means 112 of the depicted system 20 has been shown and described as including a single conduit 120 for delivering coolant to one side of the cutting tool 30 during a cutting operation, a cooling means in accordance with the broader aspects of the present invention can include a pair of conduits for delivering coolant to the opposite sides of the cutting tool 30 so that during a cutting operation, coolant is delivered to opposite sides of the cutting tool for purposes of cooling both the tool 30 and the site on the stone at which the stone is being cut by the tool 30. Accordingly, the aforedescribed embodiment is intended for the purpose of illustration and not as limitation.
Number | Name | Date | Kind |
---|---|---|---|
3841187 | Gerber et al. | Oct 1974 | A |
3844269 | Rater | Oct 1974 | A |
5318005 | Mayer | Jun 1994 | A |
6761617 | Tozawa | Jul 2004 | B2 |