LEANING GRID FOR A MITER SAW

Abstract

A leaning grid for a miter saw includes at least one upper leaning grid which is a movable leaning grid having an upper support surface for a work piece and at least one lower leaning grid having a lower support surface for the work piece. The lower leaning grid is also a movable leaning grid and may move between two support positions. The lower support surface and the upper support surface are in a same plane when the lower leaning grid is located at the support positions and the lower support surface and the upper support surface are in different planes when the lower leaning grid is located at a position that is between the support positions.

Description

RELATED APPLICATION INFORMATION

This application claims the benefit of CN 201020022763.3, filed on Jan. 8, 2010, the disclosure of which is incorporated herein by reference in its entirety.

BACKGROUND

This disclosure generally relates to miter saws and, more particularly, to a leaning grid device for a miter saw.

Miter saws are currently used in various conditions for cutting a work piece. To this end, the operator may optionally move the saw blade to any of various positions or in any of various modes so as to perform a vertical cut, an angle cut, a bevel cut or a combined miter cut.

As will be appreciated, miter saws generally include a base, a worktable rotatably connected to the base, a leaning grid assembly for supporting a work piece, and a saw mechanism pivotally connected to the worktable. Common leaning grids generally have one of two forms, namely, a stationary leaning grid and a movable leaning grid.

The body portion and the functions of a stationary leaning grid are achieved by a single member.

A movable leaning grid generally includes a lower leaning grid fixed to the base and a movable upper leaning grid movably mounted to the lower leaning grid. The support surfaces of the lower and upper leaning grids of the movable leaning grid are in a same plane to function together as a support for the work piece. The leaning grid has a plane “A” for supporting the work piece. The plane “A” is required to be vertical to the working surface of the worktable and the plane “A” of the movable leaning grid is obtained and defined together by the finally adjusted support surfaces of the lower and upper leaning grids.

When performing a miter cut, the user may move the movable leaning grid towards the outer side of the miter saw so as to prevent the saw mechanism from interfering with the movable leaning grid. The upper leaning grid of known devices may thus be arranged as a movable leaning grid in various forms:

1. A special guide groove which is parallel to the support surfaces of the leaning grid is arranged between the upper and lower leaning grids and the interference resulting from a miter cutting operation of the miter saw may be avoided by moving the movable leaning grid along the guide groove;

2. The upper and lower leaning grids are hinged with each other where the movable leaning grid may rotate with respect to the stationary leaning grid with the axis of the rotational movement being vertical to the support surfaces of the leaning grids and the interference resulting from the miter cutting operation of the miter saw may be avoided by creating various positions after rotating the movable leaning grid;

3. The upper and lower leaning grids are hinged with each other where the upper leaning grid may rotate with regard to the stationary leaning grid with the axis of the rotational movement being vertical to the support surfaces of the leaning grids and the interference resulting from the miter cutting operation of the miter saw may be avoided by creating various positions after rotating the upper leaning grid; or

4. The upper leaning grid generally has at least two positioning posts with the lower leaning grid having a plurality of positioning holes where the directions of the axes of the posts and holes are parallel to the support surfaces and the interference resulting from the miter cutting operation of the miter saw may be avoided since the different cooperating positions of the posts with the positioning holes may create different positions of the upper leaning grid.

Since the lower leaning grid in such known devices is generally a stationary leaning grid, the miter saw still has some defects. For example, it is provided in the safety standard that the distance between the support surface of the leaning grid device and the saw blade should be as small as possible so as to prevent the work piece from flying out when cutting smaller work pieces. Considering the smaller distance between the stationary leaning grid and the saw blade which may result in the interference upon a miter cutting operation, the known leaning grid device cannot meet the requirements provided by the safety standard. In order to solve this problem, a U.S. Pat. No. 5,755,148 discloses an improved leaning grid device, which has a plate respectively added between the stationary leaning grids on two sides and the saw blade to fill the space between the stationary leaning grids and the saw blade. During miter cutting, the filled plate is removed. This solution, however, increases the number of the components and the manufacture cost, and complicates operation of the saw.

SUMMARY

The subject miter saw is intended to overcome the defects existing in the prior art by providing an improved miter saw with an improved leaning grid device, which has a simple structure and may be operated conveniently.

To this end, the subject miter saw is provided with a leaning grid which is mounted to a tool body for supporting a work piece and which includes at least one upper leaning grid which is a movable leaning grid having an upper support surface for a work piece and at least one lower leaning grid which is also a movable leaning grid having a lower support surface for the work piece, wherein the lower leaning grid may move at least between a first support position and a second support position, and wherein the lower support surface and the upper support surface are in a same plane when the lower leaning grid is located at the first or second support position and are not in a same plane when the lower leaning grid is located at a position between the first and second support positions.

According to a preferred embodiment, the leaning grid also includes a bracket and at least one connecting rod with two ends pivotally connected to the bracket and the lower leaning grid respectively.

According to another preferred embodiment, the leaning grid also includes a bracket with at least two openings, and the lower leaning grid has at least one post for cooperating with the openings.

The subject miter saw may additionally include a base, a worktable, a leaning grid for supporting a work piece, and a saw mechanism pivotally connected to the worktable, wherein the saw mechanism includes a saw blade for cutting the work piece, and the leaning grid is the above the leaning grid for the miter saw.

With the above technical solutions, the subject miter saw may achieve the following technical effects:

(1) The lower leaning grid is movably connected to the bracket of the leaning grid, and therefore at least two support positions may be obtained (for example, a position adjacent to the saw blade and a position far away from the saw blade), to provide the leaning grid with a compact structure that may be used conveniently;

(2) Enough support areas may be provided in different cutting conditions; and

(3) When the miter saw is in the vertical cutting mode, the leaning grid can provide enough support area to support the work piece to be cut even if the work piece is shorter, thus it may ensure that the work piece may not fly out to thereby enhance safety.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a schematic view showing an exemplary miter saw in a usable state constructed according to the description that follows;

FIG. 2 is an exploded view showing an exemplary leaning grid of the miter saw according to a first embodiment thereof;

FIG. 3 is a bottom view showing the leaning grid of the miter saw in the assembled state according to the first embodiment thereof;

FIG. 4 is a back view showing the leaning grid of the miter saw in the assembled state according to the first embodiment thereof;

FIG. 5 is a schematic view showing the miter saw of FIG. 1 in a state usable in an extreme combined miter cutting mode;

FIG. 6 is a structural view showing an exemplary leaning grid of the miter saw according to a second embodiment thereof;

FIG. 7 is a structural view showing an exemplary leaning grid of the miter saw according to the third embodiment thereof; and

FIG. 8 is a sectional view showing the leaning grid of the miter saw according to the third embodiment thereof.

DETAILED DESCRIPTION

Preferred embodiments of the subject miter saw will now be described in detail with reference to the accompanying drawings.

Referring to FIG. 1, illustrated is a miter saw 10 which includes a base 1, a worktable 2 rotatably connected to the base 1, a saw mechanism 3 pivotally connected to the top of the worktable 2 by a support arm, a sliding rod mechanism as well as a pivot, and a leaning grid device 4. The saw mechanism 3 includes a saw blade 30 for cutting the work piece. The work piece (not shown in the drawings) may be placed on the worktable 2, and the worktable 2 and the leaning grid device 4 can be used to support the work piece together.

As shown in FIG. 1, the miter saw 10 may be used to perform an angle cut by rotating the worktable 2 which supports the saw mechanism 3 around a vertical axis with regard to the base or to perform a bevel cut by rotating the support arm around a horizontal axis with regard to the worktable 2. The structures for performing these two functions are well known to persons skilled in the art and it is therefore unnecessary to provide further detail herein.

Referring to FIGS. 1-2, a first exemplary leaning grid device 4 includes a lower leaning grid 41 with a lower support surface 410 for the work piece and an upper leaning grid 42 with an upper support surface 420 for the work piece. In a usable state, the upper and lower support surface 420, 410 are in a same plane, i.e., the above mentioned plane “A” for supporting the work piece. A bracket 5 is fixedly mounted to the base 1 for supporting the leaning grid device 4. The bracket 5 is configured to extend across the table surface of the worktable 2.

As shown in FIGS. 2-4, two symmetrical lateral rods 50 with a front surface 52 respectively are arranged on the two ends of the bracket 5. The lower leaning grid 41 has a back surface 411 parallel to the lower support surface 410 at the opposite side of the lower support surface 410 for the work piece. The leaning grid device 4 also includes a connecting rod 44 and pins 46, 47 to provide a hinge connection. The two ends of the connecting rod 44 are passed through the pins 46, 47 and are hinged to the bracket 5 and the lower leaning grid 41, respectively. The axes of the pins 46, 47 are parallel to each other and are parallel to the support surface 410 and the front surface 52. A spring 48 is used to pull the lower leaning grid 41 towards the bracket 5 so that the back surface 411 of the lower leaning grid and the front surface 52 of the bracket are kept in a closely abutted position. In order to increase the reliability and steadiness of the connection between the lower leaning grid 41 and the bracket 5 and the accuracy of the movement position of the lower leaning grid, two connecting rods 44 that are parallel to each other are provided.

As shown in FIG. 3, the lower leaning grid 41, the bracket 5, and the two connecting rods 44 form a four-bar linkage with a parallelogram shape, thus, the lower leaning grid may move between a first support position and a second support position (as indicated by the arrows). When the connecting rods 44 move towards the saw blade so that the back surface 411 of the lower leaning grid and the front surface 52 of the bracket are closely abutted, the lower leaning grid 41 is located at the first support position; whereas, when the connecting rods 44 move far away from the saw blade so that the back surface 411 of the lower leaning grid and the front surface 52 of the bracket are closely abutted, the lower leaning grid 41 is located at the second support position. When the lower leaning grid is located at the first or second support position, the lower and upper support surfaces for the work piece are in a same plane, and when the lower leaning grid is located at a position between the first and second support positions, the lower and upper support surfaces for the work piece are not in a same plane, that is to say, the lower and upper support surfaces are staggered.

The bracket 5 includes a sliding groove 51 which opens upwards, and the upper leaning grid 42 has a sliding rod 43 extending laterally at the lower end thereof correspondingly, thus the upper leaning grid 42 may slide on the bracket 5 by the cooperation of the sliding rod 43 and the sliding groove 51. The bracket 5 has a threaded hole 54, and a knob 53 passes through the threaded hole 54 and bears against the sliding rod 43 of the upper leaning grid 42, thus the upper leaning grid 42 may be fixed to the bracket 5 by screwing the knob 53.

In the presently described and illustrated embodiment, the miter saw can be used to perform bevel cutting on the two sides, thus the leaning grid devices on the two sides of the saw blade has the same structure. With regard to a miter saw for bevel cutting on only one side, the leaning grid device may be mounted to only one side of the saw blade in order to reduce the manufacture cost.

As shown in FIG. 1, the miter saw is in a vertical cutting mode. In this operational mode, the user may move the leaning grid device 4 towards the saw blade 30 to a position proximal to the saw blade 30. At that moment, the distance between the saw blade 30 and the support surfaces 410, 420 is the smallest, thus the work piece cannot fly out of the space between the saw blade 30 and the support surfaces 410, 420 when cutting shorter work pieces, thereby enhancing safety.

As shown in FIG. 5, the miter saw 10 is in an extreme combined miter cutting mode. In this operational mode, the saw mechanism 3 is not only inclined towards one side to an extreme position for bevel cutting, but also rotated with regard to the base to an extreme position for angle cutting, thus the saw mechanism 3 is prone to interfere with the leaning grid device 4. The user may release the knob 53 so as to move the upper leaning grid 42 outwards and screw the knob 53 when the upper leaning grid 42 is moved to the outermost side. The lower leaning grid 41 is simultaneously pulled horizontally forwards and pushed far away from the saw blade. The outwards pull operation is stopped when the lower leaning grid 41 leaves the bracket 5 to a farthest point. With the push force and the pull force of the spring, the front surface 52 of the bracket and the back surface 411 of the lower leaning grid are closely abutted together. At that moment, both of the lower leaning grid 41 and the upper leaning grid 42 are far away from the saw blade, thereby avoiding the interference between the saw blade and the leaning grids caused by the extreme combined miter cutting.

The above description illustrates an exemplary first embodiment wherein the leaning grid device 4 is mounted to the base indirectly by a bracket. However, in other embodiments, the leaning grid device 4 may also be mounted to the base 1 directly, wherein the bracket 5 and the base 1 are formed integrally.

Referring to FIGS. 1 and 6, similar to the first embodiment, a second embodiment of the leaning grid device 4 includes a lower leaning grid 41 with a lower support surface 410 for the work piece and an upper leaning grid 42 with an upper support surface 420 for the work piece. In a usable state, the upper and lower support surfaces 420, 410 are in a same plane, i.e., the above mentioned plane “A” for supporting the work piece. A bracket 5 is fixedly mounted to the base 1 for supporting the leaning grid device 4. The bracket 5 is configured to extend across the table surface of the worktable 2.

As same as the exemplary first embodiment, the upper leaning grid 42 and the bracket 5 may achieve a sliding adjustment in the horizontal direction by the cooperation of a groove and a rod.

The second, exemplary embodiment differs from the first, exemplary embodiment in that the lower leaning grid 41 is provided with at least one post 49 (preferably, more than two posts are arranged), and the corresponding bracket 5 is provided with at least two openings 54 for mating with the post 49, which may obtain at least two support positions to achieve a support function for the miter saw on different cutting positions by the staggerable cooperation of the post and the openings.

It will be appreciated by person skilled in the art that the sections of the post 49 and the openings 54 may be circular shape or non-conventional type shapes. Moreover, the openings 54 may be arranged in the lower leaning grid 41 while the post 49 for mating with the openings may be arranged in the bracket 5.

Referring to FIGS. 1 and 87, similar to the exemplary first embodiment, an exemplary third embodiment of the leaning grid device 4 includes a lower leaning grid 41 with a lower support surface 410 for the work piece and an upper leaning grid 42 with an upper support surface 420 for the work piece. In the usable state, the upper and lower support surfaces 420, 410 are in a same plane, i.e., the above mentioned plane “A” for supporting the work piece. A bracket 5 is fixedly mounted to the base 1 for supporting the leaning grid device 4. The bracket 5 is configured to extend across the table surface of the worktable 2.

As same as the first, exemplary embodiment, the upper leaning grid 42 and the bracket 5 may achieve a sliding adjustment in the horizontal direction by the cooperation of a groove and a rod.

As same as the second, exemplary embodiment, the lower leaning grid 41 is provided with at least one post 49, and the corresponding bracket 5 is provided with at least two openings 54 for mating with the post 49, which may obtain at least two support positions to achieve a support function for the miter saw on different cutting positions by the staggerable cooperation of the post and the openings.

Additionally, referring to FIGS. 7-8, the bracket of the leaning grid is provided with an elastic sheet 55. With the elastic sheet 55, the lower leaning grid 41 may approach the bracket 5 as close as possible so as to ensure that the support surface 410 of the lower leaning grid 41 is close to the required plane “A.”

While exemplary embodiments have thus been described and illustrated, it is to be understood that the miter saw and the leaning grid so described and illustrated are not to be limit according to the structures shown in the drawings. For example, the fixing manner between the lower leaning grid and the bracket is not to be limited to the structures in the above embodiments. Rather, any changes, replacements, or modifications for the shape or position of such elements are to be regarded as falling within the protective scope of the claims set forth below.

Claims

1. A leaning grid for a miter saw, which is mounted to a tool body for supporting a work piece, comprising: at least one upper leaning grid which is a movable leaning grid having an upper support surface for the work piece; andat least one lower leaning grid having a lower support surface for the work piece;wherein the lower leaning grid is also a movable leaning grid and is moveable between a first support position and a second support position and wherein the lower support surface and the upper support surface are in a same plane when the lower leaning grid is located at the first or second support position and the lower support surface and the upper support surface are in different planes when the lower leaning grid is located at a position that is between the first and second support positions.

2. The leaning grid for a miter saw according to claim 1, wherein the leaning grid comprises a bracket and at least one connecting rod and two ends of the connecting rod are pivotally connected to the bracket and the lower leaning grid, respectively.

3. The leaning grid for a miter saw according to claim 2, wherein the two connecting rods are positioned to be parallel to each other.

4. The leaning grid for a miter saw according to claim 2, comprising a spring having two ends that are connected to the bracket and the lower leaning grid, respectively.

5. The leaning grid for a miter saw according to claim 1, wherein the leaning grid comprises a bracket having at least two openings and the lower leaning grid is provided with at least one post for mating with the openings.

6. The leaning grid for a miter saw according to claim 5, wherein the leaning grid comprises an elastic sheet which is mounted to the bracket for pulling the lower leaning grid towards the bracket.

7. The leaning grid for a miter saw according to claim 2, wherein the bracket is fixedly connected to a base of a body of the miter saw assembly.

8. The leaning grid for a miter saw according to claim 2, wherein the bracket is integrally formed as a part of a base of the miter saw assembly.

9. A miter saw, comprising: a base;a worktable;a leaning grid for supporting a work piece; anda saw mechanism which is pivotally connected to the worktable and which includes a saw blade for cutting the work piece;

10. The miter saw according to claim 9, wherein the leaning grid comprises a bracket and at least one connecting rod and two ends of the connecting rod are pivotally connected to the bracket and the lower leaning grid, respectively.

11. The miter saw according to claim 10, wherein the two connecting rods are positioned to be parallel to each other.

12. The miter saw according to claim 10, comprising a spring having two ends that are connected to the bracket and the lower leaning grid, respectively.

13. The miter saw according to claim 9, wherein the leaning grid comprises a bracket having at least two openings and the lower leaning grid is provided with at least one post for mating with the openings.

14. The miter saw according to claim 13, wherein the leaning grid comprises an elastic sheet which is mounted to the bracket for pulling the lower leaning grid towards the bracket.

15. The miter saw according to claim 10, wherein the bracket is fixedly connected to the base.

16. The miter saw according to claim 10, wherein the bracket is integrally formed as a part of the base.