SAFETY LOCK MECHANISM FOR TRIGGER SWITCH HANDLE OF MITER SAW

Abstract

A safety lock mechanism mounted at a trigger switch handle of a miter saw to face toward a switch which includes a switch button pivotally mounted at the trigger switch handle to face toward the switch, and a safety lock connected to the switch button and providing an engaging portion and movable between a locking position where the engaging portion engages into the trigger switch handle to lock the switch button to the trigger switch handle and an unlocking position where the engaging portion is disengaged from the trigger switch handle for allowing the switch button to be moved relative to the trigger switch handle to trigger the switch. Thus, the arrangement of the safety lock prevents the user from accidentally forcing the switch button to trigger the switch, enhancing the operational safety of the miter saw.

Claims

1. A safety lock mechanism mounted on a trigger switch handle, the safety lock mechanism comprising: a switch button pivotally mounted on said trigger switch handle that is able to be engaged with a switch; and a safety lock comprising an engaging portion, said safety lock being connected to said switch button and movable between a locking position where said engaging portion engages said trigger switch handle to lock said switch button to said trigger switch handle, and an unlocking position where said engaging portion is disengaged from said trigger switch handle to allow said switch button to be moved relative to said trigger switch handle to trigger said switch.

2. The safety lock mechanism as claimed in claim 1, wherein said safety lock is pivotally connected to said switch button and biasable relative to said switch button to lock said switch button to said trigger switch handle.

3. The safety lock mechanism as claimed in claim 1, wherein said safety lock is slidably connected to said switch button and linearly movable relative to said switch button to lock said switch button to said trigger switch handle.

4. The safety lock mechanism as claimed in claim 2, further comprising an elastic member mounted between said switch button and said safety lock and adapted to impart an elastic potential energy to said safety lock, forcing said safety lock to bias said engaging portion toward said locking position.

5. The safety lock mechanism as claimed in claim 3, further comprising an elastic member mounted between said switch button and said safety lock and adapted to impart an elastic potential energy to said safety lock, forcing said safety lock to bias said engaging portion toward said locking position.

6. The safety lock mechanism as claimed in claim 1, wherein said trigger switch handle comprises an end surface and a sliding groove located on said end surface; wherein said switch is mounted inside said sliding groove; said switch button is pivotally mounted in said sliding groove; wherein said engaging portion is stopped against said end surface of said trigger switch handle when said safety lock is in said locking position; and said engaging portion is moved away from said end surface of said trigger switch handle and received in said sliding groove when said safety lock is in said unlocking position.

7. The safety lock mechanism as claimed in claim 6, further comprising a return spring mounted between said switch button and said trigger switch handle and adapted to impart an elastic potential energy to said switch button and said safety lock, forcing said safety lock to bias said engaging portion toward the outside of said sliding groove.

8. The safety lock mechanism as claimed in claim 1, wherein said switch button comprises a top surface, a bottom surface disposed opposite to said top surface to face toward said switch, two opposing lateral surfaces connected between said top surface and said bottom surface, a notch extended from said top surface toward said bottom surface and cut through said lateral surfaces and a pin hole facing toward said notch; said safety lock further comprises an operating portion disposed opposite said engaging portion and mounted in said notch, a pivot hole disposed between said operating portion and said engaging portion and an axle pin inserted through said pivot hole and fastened to said pin hole.

9. The safety lock mechanism as claimed in claim 2, wherein said switch button comprises a top surface, a bottom surface disposed opposite to said top surface to face toward said switch, two opposing lateral surfaces connected between said top surface and said bottom surface, a notch extended from said top surface toward said bottom surface and cut through said lateral surfaces and a pin hole facing toward said notch; said safety lock further comprises an operating portion disposed opposite to said engaging portion and mounted in said notch, a pivot hole disposed between said operating portion and said engaging portion and an axle pin inserted through said pivot hole and fastened to said pin hole.

10. The safety lock mechanism as claimed in claim 8, wherein said safety lock further comprises a plurality of anti-slip ribs arranged on said operating portion.

11. A trigger switch handle comprising: a safety lock mechanism mounted on the trigger switch handle, said safety lock mechanism comprising: a switch button pivotally mounted on said trigger switch handle that is able to be engaged with a switch; and a safety lock comprising an engaging portion, said safety lock being connected to said switch button and movable between a locking position where said engaging portion engages said trigger switch handle to lock said switch button to said trigger switch handle, and an unlocking position where said engaging portion is disengaged from said trigger switch handle to allow said switch button to be moved relative to said trigger switch handle to trigger said switch.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0012] FIG. 1 is an oblique top elevational view, illustrating a safety lock mechanism installed in a miter saw's trigger switch incorporated handle in accordance with the present invention.

[0013] FIG. 2 is an elevational view, in an enlarged scale, of the trigger switch incorporated handle shown in FIG. 1.

[0014] FIG. 3 is an exploded view of the trigger switch incorporated handle shown in FIG. 2.

[0015] FIG. 4 is a plan view illustrating the arrangement of the safety lock mechanism in the trigger switch incorporated handle in accordance with the present invention.

[0016] FIG. 5 is a sectional view taken along line V-V of FIG. 4, illustrating the safety lock set in the locking position in the trigger switch incorporated handle.

[0017] FIG. 6 is a schematic operational view of the present invention, illustrating the safety lock moved to the unlocking position.

[0018] FIG. 7 is another schematic operational view of the present invention, illustrating the safety lock moved in the trigger switch incorporated handle and triggered the switch button.

DETAILED DESCRIPTION OF THE INVENTION

[0019] Referring to FIGS. 1 and 2, a safety lock mechanism in accordance with the present invention is shown installed on a trigger switch incorporated handle 2 corresponding to a switch 1. The trigger switch incorporated handle 2 is installed in a saw unit 3 of a miter saw. The safety lock mechanism comprises a switch button 10, a safety lock 20, an elastic member 30, and a return spring 40.

[0020] In the present preferred embodiment, the trigger switch incorporated handle 2 is the operating handle of the saw unit 3, comprising a connection portion 201 connected to the saw unit 3 and a grip portion 202 connected to one side of the connection portion 201 opposite to the saw unit 3. The grip portion 202 comprises two opposing sidebars 203 connected to the connection portion 201 and a transverse bar 204 connected between the sidebars 203. The transverse bar 204 defines an end surface 205 and a sliding groove 206. The sliding groove 206 is located on the end surface 205 and extended to an inner side of the transverse bar 204. The connection portion 201, the sidebars 203 and the transverse bar 204 surround an opening 207 that is disposed in communication with the sliding groove 206. Further, a pivot rod 208 is located at the connection area between the sidebars 203 and the transverse bar 204. The switch 1 is mounted in the transverse bar 204 inside the sliding groove 206, comprising a triggering portion 101 that faces toward the open side of the sliding groove 206.

[0021] The switch button 10 is shaped like a rectangular block and pivotally mounted in the sliding groove 206 of the trigger switch incorporated handle 2 to face toward the switch 1, comprising a top surface 11 disposed adjacent to the opening 207, a bottom surface 12 disposed opposite to the top surface 11 to face toward the switch 1, two opposing lateral surfaces 131,132 connected to the top surface 11 and the bottom surface 12, a notch 14 extended from the top surface 11 to the bottom surface 12 and abutted to the two opposing lateral surfaces 131,132, a pin hole 15 facing toward the notch 14, a trigger block 16 protruded from the bottom surface 12, and a pivot-connection portion 17 located at one end of the bottom surface 12 and pivotally coupled to the pivot rod 208. The notch 14 comprises a shallow side 141 extended from the top surface 11 toward the bottom surface 12 and cut through one lateral surface 131, and a deep side 142 extended from the top surface 11 toward the bottom surface 12 and cut through the other lateral surface 132. The switch button 10 further comprises a protruding rod 18 facing toward the deep side 142 (see FIG. 5).

[0022] The safety lock 20 is pivotally connected to the switch button 10 and disposed in the notch 14, comprising an engaging portion 21 suspended or mounted in the deep side 142, an operating portion 22 disposed opposite the engaging portion 21 and mounted in the shallow side 141, a pivot hole 23 disposed between the operating portion 22 and the engaging portion 21, an axle pin 24 inserted through the pivot hole 23 and fastened to the pin hole 15, a plurality of anti-slip stripes 25 arranged on the operating portion 22, and a retaining groove 26 located on the engaging portion 21 to face toward the protruding rod 18.

[0023] In the present preferred embodiment, the elastic member 30 is a compression spring mounted between the switch button 10 and the safety lock 20 with two opposing ends thereof respectively attached to the protruding rod 18 and the retaining groove 26. The elastic restoring force of the elastic member 30 forces the safety lock 20 to bias the engaging portion 21 thereof toward a locking position (see FIG. 5).

[0024] In the present preferred embodiment, the return spring 40 is a compression spring mounted between the switch button 10 and the trigger switch handle 2. The elastic restoring force of the return spring 40 forces the switch button 10 and the safety lock 20 to bias toward the outside of the sliding groove 206, keeping the engaging portion 21 of the safety lock 20 out of the sliding groove 206.

[0025] Further, FIG. 5 illustrates the safety lock 20 forced by the elastic restoring force of the elastic member 30 to hold the engaging portion 21 thereof in the locking position where the engaging portion 21 extends out of the deep side 142 of the notch 14 and held in position relative to the end surface 205 of the trigger switch handle 2. If the user presses the top surface 11 of the switch button 10 at this time, the engaging portion 21 keeps its position on the end surface 205 of the trigger switch handle 2 to prohibit the trigger block 16 from triggering the triggering portion 101 of the switch 1.

[0026] Further, as illustrated in FIG. 6, when the user is going to start a cutting operation and holds the trigger switching handle 2 by hand, the user can press the operating portion 22 of the safety lock 20 with the hand that holds the transverse bar 204, which moves the operating portion 22 from the shallow side 141 toward the deep side 142. At this time, the engaging portion 21 is moved toward the protruding rod 18 to an unlocking position (at this time, the elastic member 30 is compressed to preserve an elastic potential energy). When the unlocking position is reached, the engaging portion 21 is moved away from the end surface 205 to release the trigger switch handle 2 from the constraint of such movement.

[0027] Referring to FIG. 7 and FIG. 3, when the user presses the top surface 11 of the switch button 10 after the trigger switch handle 2 is released from the constraint of the engaging portion 21, the pivot-connection portion 17 of the switch button 10 is turned about the pivot rod 208 to move the safety lock 20 toward the inside of the sliding groove 206 (at this time, the return spring 40 is compressed to preserve an elastic potential energy) until the trigger block 16 touches the triggering portion 101 of the switch 1 to switch on the power supply of the saw unit.

[0028] After the cutting operation, the user releases the switch button 10, enabling the switch button 10 and the safety lock 20 to be biased by the elastic potential energy of the return spring 40 to suspend or position the engaging portion 21 outside the sliding groove 206, where the engaging portion 21 is then forced by the elastic potential energy of the elastic member 30 to move from the unlocking position back to the locking position shown in FIG. 5.

[0029] In the present preferred embodiment, the switch 1 can be micro switch, trigger switch or any other equivalent switch means for energizing the saw unit. Further, not only can the safety lock 20 be pivotally connected to the switch button 10, the safety lock 20 can be slidably coupled to the switch button 10 and linearly moved between the locking position to lock the switch button 10 to the trigger switch handle 2 and the unlocking position to unlock the switch button 10 from the trigger switch handle 2 to achieve the same effect.

[0030] Thus, the invention has the safety lock 20 mounted to the switch button 10 and, the user must move the safety lock 20 from the locking position to the unlocking position before operation so that the power supply of the saw unit 3 can be switched on for performing a cutting operation, which avoids the risk of operational errors which may cause danger. Further, the overall structure of the safety lock mechanism is simple, facilitating fabrication, installation and safety lock operation. In view of the above, the safety lock mechanism of the present invention solves the technical problems of the prior art designs, and surely achieves the object of the present invention.

[0031] Although a particular embodiment of the invention has been described in detail for purposes of illustration, various modifications and enhancements may be made without departing from the spirit and scope of the invention. Accordingly, the invention is not to be limited except as by the appended claims.