MITER SAW LINEAR MOVEMENT ASSEMBLY

Abstract

A miter saw assembly is presented as a power tool, the miter saw assembly includes a base; a fixture supported on said base; a proximal pair of arms, hinged with four hinges to said fixture at a first hinge point; a gear box plate, hinged with four hinges to said proximal pair of arms at a second hinge point; a distal pair of arms, hinged with four hinges to said gear box at a first end, and a second end hinged with four hinges to said distal pair of arms; a gearing assembly hinged to said gear box plate, with a first gear attached to a first one of said proximal pair of arms and a second gear attached to a first one of said distal pair of arms, and a rotary saw, mounted to said second end of said distal pair of arms.

Claims

1. A miter saw assembly, comprising: (a) a base; (b) a fixture supported on said base; (c) a proximal pair of arms, having a first length, and hinged to said fixture at a pair of first hinges, such that said proximal pair of arms can swing through a movement plane and having a second pair of hinges opposed to said first pair of hinges; (d) a gear box plate hinged in said first dimension to said proximal pair of arms at said second hinge points, and wherein said proximal pair of arms are shaped, said first pair of hinges are positioned on said fixture, and said second hinges are positioned on said gear box plate, such that said gearbox does not change orientation as it is moved about said fixture; (e) a distal pair of arms, having a second length, and shaped and hinged to said gear box plate at a first end, and having a second end, opposed to said first end; (f) a rotary saw sub-assembly, mounted to said second end of said distal pair of arms. (g) a gearing assembly hinged to said gear box plate, but having a first gear rigidly attached to a first one of said proximal pair of arms and a second gear, engaged to said first gear, and rigidly attached to a first one of said distal pair of arms, so that said rotary saw sub-assembly is permitted to move in a first dimension of said movement plane, but remains stationary in a second dimension, orthogonal to said first dimension, as it moves through said first dimension.

2. The miter saw assembly of claim 1, wherein said gearing assembly causes the angle of said first one of said distal pair of arms, as defined by its hinge-to-hinge line segment, relative to said first dimension, to equal: $\mathrm{Arccos}\left(\frac{l.Math..Math.\cos .Math..Math.\theta -h}{l^{\prime }}\right)$ where l is the proximal arm length, l′ is the distal arm length, both defined as length from hinge-to-hinge, θ is the angle of the first one of said proximal pair of arms, relative to said first dimension, and h is the difference in position, in said first dimension, between said fixture and said rotary saw subassembly, divided by the distal arm length.

3. The miter saw assembly of claim 1, wherein said first dimension is vertical.

4. The miter saw assembly of claim 1, wherein said rotary saw sub-assembly is mounted on said end of said distal pair of arms by being hinged to a rotary saw fixture that is hinged to each of said distal ends of said distal pair of arms.

5. The miter saw assembly of claim 1, further including a second gear box plate, displaced horizontally from said gear box plate, and wherein said gearing assembly is supported between said gear box plate and said second gear box plate.

6. The miter saw assembly of claim 1, where at least two of said arms include a horizontally spaced pair of lengthwise elements, joined together by a plate.

7. The miter saw assembly of claim 6, wherein said at least two of said arms have a width of at least 10 cm.

8. The miter saw assembly of claim 6, wherein said at least two of said arms have a width of at least 15 cm.

9. The miter saw assembly of claim 6, wherein said lengthwise elements of said at least two of said arms are individually hinged to one of said brackets.

10. The miter saw assembly of claim 4, wherein said lengthwise elements of said at least two of said arms are hinged to one of said brackets by a rod that extends through each lengthwise element of an arm.

11. The miter saw assembly of claim 1, wherein said distal arms and said proximal arms are the same length, and wherein said first gear and said second gear are mutually equal, so that the angle of said distal pair of arms, relative to said first dimension, equals that of said proximal pair of arms, relative to said first dimension.

12. The miter saw assembly of claim 1, further including a work piece support, supported by said base.

13. The miter saw assembly of claim 1, wherein said work piece support defines a slot for accommodating said circular saw blade.

14. The miter saw assembly of claim 1, wherein said proximal and distal arms are mirror images of each other, and the gears have a consistent 1:1 ratio.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0007] Exemplary embodiments are illustrated in referenced drawings. It is intended that the embodiments and figures disclosed herein are to be considered illustrative rather than restrictive.

[0008] FIG. 1 is an isometric view of a miter saw assembly, including a linear movement assembly.

[0009] FIG. 2 is a side view of the linear movement assembly of FIG. 1.

[0010] FIG. 3 is a side view of an alternate embodiment of a linear movement assembly, that could be used in the miter saw assembly of FIG. 1.

DETAILED DESCRIPTION OF THE INVENTION

[0011] Referring to FIG. 1, a miter saw assembly 10 includes a base 12 supporting a bracket 14 and work piece support 16, defining a slot (not shown) to accommodate a circular saw blade 18, as it saws through a work piece. A horizontal blocking element 19 (also with a cleft to accommodate the blade) constrains a work piece horizontally, during sawing. The circular saw blade 18 is part of a rotary saw sub-assembly 20, which further includes an electric motor 22 and a drive mechanism 24 (with only the belt cover shown). A linear movement assembly (LMA) 30 is mounted on bracket 14 and is connected to circular saw sub-assembly at hinge 32.

[0012] Referring to FIG. 2, now, in addition to FIG. 1, a proximal pair of arms, including a proximal upper arm 34 and a proximal lower arm 36, are hinged to bracket 14 at hinges 37 and to a gearbox plate 38, at hinges 40. Arms 34 and 36 are shaped and arranged so that as they rotate about their respective hinges 37, gearbox plate 38 maintains an unchanging orientation as it moves in an essentially arcuate manner. A second gearbox plate (not shown) is displaced horizontally from gearbox plate 38, with a gearing assembly (described below) located in between second gearbox plate and gearbox plate 38. A distal pair of arms 44 and 46 are connected between gearbox plate 38 and an end bracket 42, and are hinged to gearbox plate 38 at hinges 40, and to bracket 42 (which terminates at hinge 32, connecting to the miter saw assembly 20) at hinges 48. The rotary saw sub-assembly 20 is mounted on the end of the distal pair of arms by being hinged to bracket 42 that is hinged to each end of each distal arm 44 and 46.

[0013] A pair of gears, 50 and 52, are rigidly attached, by way of splines 54, to upper arms 34 and 44, respectively, so that the angle relationship between arms 34 and 44 is set by the gears 50 and 52, as arms 34 and 44 rotate through their arcs. In order to keep bracket 42 at a constant vertical position, the angle θ′ between vertical and a line segment LS.sub.2 must obey the following equation:

[00001]${\theta }^{\prime }=\mathrm{Arccos}\left(\frac{l.Math..Math.\cos .Math..Math.\theta -h}{l^{\prime }}\right)$

[0014] Where θ is the angle between vertical and line segment LS.sub.1, l is the length of line segment LS.sub.1, l ′ is the length of line segment LS.sub.2, and his the vertical position difference between the proximal uppermost hinge 37 and the distal uppermost hinge 48. If l equals l′, and h=0, this equation reduces to θ′=θ. In one embodiment his set to equal (l−l′).

[0015] This embodiment, in which the proximal and distal arms match, may have a set of matching, circular toothed gears. If the arms are of unequal length, however, the gears cannot be circular. in order to have a correct gearing relationship, in one embodiment the gears do not have teeth, as shown, but have non-slip surfaces. In another embodiment in which l does not equal l′, gears 50 and 52 are toothed gears, but are constructed to have the required relationship.

[0016] Two of the arms (34 and 44) include a horizontally spaced pair of lengthwise elements 60, joined together by a plate 62. The lengthwise elements 60 are individually hinged to one of the brackets 14 or 44. Two of the arms may have a width of at least 10 cm. Additionally; two of the arms 34 and 44 have a width of at least 15 cm.

[0017] Referring to FIG. 3, in an alternative embodiment, axles 55 and 56 are added and gears 50′ and 52′ replace gears 50 and 52.

[0018] Referring, again, to FIG. 1 in a preferred embodiment a cover 70 protects gears 50 and 52 from saw dust and dirt. Additional housing features may also be used to protect gears 50 and 52 from saw dust and dirt. Although the linear movement assembly 30 is shown as being vertically hinged, with elements moving vertically, as well as in the direction of linear movement of the rotary saw sub-assembly 20, in an alternative preferred embodiment, the elements are hinged horizontally, in a dimension orthogonal to the direction of linear movement.