JP5020644B2 - Power tool switch - Google Patents

Description

  The present invention relates to a switch for activation operation provided in a handle portion gripped by a user in an electric tool such as a portable circular saw.

The portable circular saw includes a handle portion for a user to hold. The handle portion has, for example, a loop shape. For example, a trigger-type switch is provided on the inner peripheral side of the handle portion. This switch includes a switch lever that a user pulls with a fingertip, and a switch body that is turned on by pulling the switch lever (on operation). The user can turn on the switch body by pulling the switch lever with the fingertip while holding the handle portion, thereby starting the electric motor built in the tool body and rotating the circular cutting blade. be able to. Conversely, the electric motor can be stopped by releasing the pulling operation of the switch lever.
Normally, this type of switch is devised to prevent erroneous operation or inadvertent on-operation. For example, the switch lever has a so-called idle running distance (play), and the switch body is turned on when the switch lever is operated to the ON side for a certain distance. When it is not possible to secure a free running distance, a so-called lock-off mechanism is provided separately from the switch lever to prohibit the switch lever from being turned on, thereby preventing erroneous operation of the switch. ing.
JP-A-11-170203 JP-A-10-109302

However, the conventional switch has the following problems. That is, conventionally, the switch lever is integrally provided at the tip of the switch knob of the switch body (knob-integrated switch lever), and when the switch lever is pulled, the switch knob moves integrally. The idle distance of the lever and the idle distance of the switch knob matched. For this reason, in the case of an electric tool that uses a relatively small switch, it is difficult to ensure a larger idle travel distance although an idle travel distance of about 4 mm to 5 mm is set for the switch lever. As a result, it is necessary to provide a separate lock-off mechanism in order to further improve the erroneous operation prevention function.
The present invention has been made to solve this problem. In the case of a power tool using a relatively small switch, the switch is not provided with a separate lock-off mechanism, and the conventional switch body is used as it is. It is an object of the present invention to prevent erroneous operations and the like more reliably by setting a sufficiently large idling distance to the lever.

Said subject is solved by each following invention.
According to a first aspect of the present invention, there is provided a switch lever that is operated by a user of the power tool, and a rod-shaped lever that moves to the on position side by an idle travel distance L2 by moving the switch lever to the on position side. have a switch knob, a switch with switch body having a knob biasing means for biasing the switch knob at one end in the longitudinal direction of the switch knob,
A lever idling distance imparting means for making the idling distance L as an operation amount of the switch lever necessary for turning on the switch main body larger than the idling distance L2 of the switch knob is provided on the switch body. Provided outside, the lever idle distance means is provided with a lever urging means between the switch lever and the switch knob, and the switch knob does not move from the off position while the switch lever moves to the on position side by a certain distance. It is.
According to the first aspect of the invention, since the idle travel distance (so-called play) is provided between the switch lever and the switch knob in the operation direction to the on side, the switch lever is on the on side for the idle travel distance. The switch body turns on after the operation. Therefore, compared to the conventional knob-integrated switch lever in which the switch lever is provided integrally with the switch knob and the idle travel distance of both is the same, the idle travel distance between the switch lever and the switch knob is the same. The idle travel distance of the switch lever can be increased.
For this reason, in a relatively small switch used for an electric tool, the switch body (free running distance L2 of the switch knob) is used as it is without any change without providing a lock-off mechanism. By appropriately setting the idling distance between the lever and the switch knob, the idling distance of the switch lever can be made larger than before, and erroneous operation thereof can be prevented more reliably.
In addition, as described above, there is no need to make any special changes to the switch body, so that the conventional switch body can be used as it is, and the switch lever idle distance can be divided into a type with a large idle distance and a type with a small idle distance. Changes or switching can be easily performed.
In this specification, the “idle travel distance” of the switch lever means a distance (so-called play) that the user moves from the non-operating position of the switch lever that is directly operated by a fingertip or the like until the switch body is turned on. To do.
According to a second aspect of the invention, in the first aspect of the invention, the switch having the idle travel distance L1 is provided between the switch lever and the switch knob via a lever urging spring that urges the switch lever toward the off position. It is.
According to the second invention, in the switch according to the first invention, the movement operation of the switch lever performed against the lever biasing spring corresponds to the idling distance. When the switch lever is not operated, the idle travel distance is always held at the maximum side by the lever biasing spring.
The following third to fifth inventions are related inventions not included in the claims .
According to a third aspect of the present invention, there is provided a switch lever that is operated by a user of the power tool, and a switch knob that moves to the on position side by the idle travel distance L2 by moving the switch lever to the on position side and reaches the on position. A switch having a switch body having a switch body that is movably supported with respect to a switch support portion of an electric tool, and the switch body is moved by an operation of moving the switch lever to an on position side. This is a switch having a free running distance L3 for the operation of moving to the ON position side.
According to the third invention, when the switch lever is moved to the ON side, the switch body first moves, and then the switch knob moves to turn on the switch body. For this reason, the idle travel distance of the switch lever is the total of the travel distance of the switch body and the travel distance of the switch knob, and the idle travel distance of the switch body must be made larger than before by the amount corresponding to the travel distance of the switch body. Can do.
For this reason, in a relatively small switch used for an electric power tool, the distance traveled by the switch lever can be made larger than before by appropriately setting the moving distance of the switch body without providing a separate lock-off mechanism. Misoperations can be prevented more reliably. In this case, since there is no need to make any special changes to the switch body, the switch body of the conventional configuration (the idle travel distance L2 of the switch knob) can be used as it is, and the switch lever play can be changed or switched. It can be done easily.

According to a fourth invention, in the third invention, a main body biasing spring for biasing the switch body toward the off position side, and a knob biasing spring for biasing the switch knob toward the off position side, the knob biasing spring. The switch is configured to move the switch body to the ON position side against the body biasing spring as the switch lever is moved to the ON position side by setting the biasing force of the body biasing spring to be smaller. is there.
According to the fourth invention, when the switch lever is operated to be turned on, the switch body first moves against the body biasing spring. The travel distance of the switch body corresponds to the idle travel distance of the switch lever. After the switch body moves a certain distance against the body biasing spring, if the switch lever is further moved to the on side against the body biasing spring and the switch knob biasing spring, the switch knob moves to the on side. The switch body turns on. From this, it is possible to reliably prevent an erroneous operation or the like by setting a larger idling distance of the switch lever than the conventional one as described above. Further, since the switch knob and the switch main body are each returned to the off-side position by the spring, the idle travel distance of the switch lever is maintained at the maximum when the switch lever is not operated.
According to a fifth aspect of the present invention, there is provided a switch lever that is operated by a user of the electric tool, and a switch knob that moves to the on position side by an idle travel distance L2 by moving the switch lever to the on position side and reaches the on position. The switch lever is supported by the switch lever support portion of the electric tool so that it can be tilted about the tilt fulcrum, and a switch knob is provided between the tilt tip and the tilt fulcrum. And the idle travel distance L2 of the switch knob is amplified based on the ratio of the distance R1 between the knob abutting portion and the tilting fulcrum and the distance R2 between the tilting tip and the tilting fulcrum. The switch lever has a free running distance L4 .
According to the fifth invention , if the fingertip is hooked on the tilting operation portion of the switch lever supported by tilting and the switch lever is pulled to the ON side (tilting operation), the switch knob moves to the ON side at the same time. Operated.
The ratio of the moving operation amount (idle distance) to the switch knob on position and the moving amount of the switch lever is the distance between the tilt fulcrum and the switch knob abutment (tilt radius R1), the tilt fulcrum The idle travel distance of the switch knob is amplified based on the ratio (R2 / R1) to the distance (tilt radius R2) between the tilt end of the switch lever and converted into the idle travel distance of the tilt operation section. For this reason, the idle travel distance of the switch lever is compared with that of the conventional knob integrated switch lever where the idle travel distance of the switch lever matches the idle travel distance of the switch knob. Can be made sufficiently large (amplified). Therefore, in a switch of a power tool in which a relatively small one is used, it is possible to sufficiently prevent a misoperation or the like by sufficiently securing the idle travel distance of the switch lever without using a separate lock-off mechanism. .
Also in this case, since there is no need to change the switch body itself, the switch body having the conventional configuration (switch knob idle travel distance L2) can be used as it is, and the idle travel distance of the switch lever can be easily changed or switched. To be able to do that.
According to a sixth aspect of the present invention, there is provided a switch lever that is operated by a user of the electric tool, and a switch knob that moves to the on position side by an idle travel distance L2 by moving the switch lever to the on position side and reaches the on position. A switch provided with a switch body having a lever idle travel distance for making the idle travel distance L as an operation amount of the switch lever necessary to turn on the switch body larger than the idle travel distance L2 of the switch knob It is a switch provided with a giving means .
According to the sixth aspect of the invention , the amount of operation of the switch lever (idle distance L) required for turning on the switch body is greater than the idle distance L2 of the switch knob by the lever idling distance imparting means. . For this reason, it is possible to increase the idle travel distance of the switch lever as compared with the conventional lever-integrated switch knob, and thus, in a relatively small switch used for the electric tool, without providing a separate lock-off mechanism, The idle travel distance of the switch lever can be made larger than that of the conventional knob-integrated switch lever, and erroneous operation thereof can be prevented more reliably.
As described above, the lever idle travel distance imparting means for making the idle travel distance L of the switch lever larger than the idle travel distance L2 of the switch knob itself can take various forms. For example, a configuration in which an idle travel distance L1 is set between the switch knob and the switch knob of the switch body, a configuration in which the switch body itself is moved to be an idle travel distance L3 with respect to the switch knob of the switch lever, and a mode in which the switch lever is tilted. As described above, by amplifying the idle travel distance L2 of the switch knob itself by a ratio based on the difference in distance from the tilt center, the required travel distance (idle travel distance L4) of the tilting tip of the switch lever is set large. This can be set as the free running distance L.
Further, according to the sixth aspect of the invention , the switch body (the idle travel distance L2 of the switch knob) can be used as it is without any particular change. It becomes possible to easily switch or change to a type with a small free running distance.

Next, an embodiment of the present invention will be described with reference to FIGS . 1 to 5 and related embodiments with reference to FIGS . FIG.1 and FIG.2 has shown the portable circular saw 1 provided with the switch 10 which concerns on 1st Embodiment. The circular saw 1 according to the present embodiment is characterized by the activation switch 10, and the basic configuration as the other cutting machine is not particularly changed. The circular saw 1 is placed on the upper surface of the cutting material and is moved by the user to perform a cutting operation. The overall configuration will be briefly described below.
In FIG. 1, the code | symbol 2 has shown the base contact | abutted on the upper surface of a cutting material. A blade case 3 is supported on the upper surface of the base 2. The blade case 3 covers a range of the upper half circumference of the circular blade (cutting blade) 4. The lower side of the blade 4 protrudes to the lower surface side of the base 2, and this protruding portion is cut into the cutting material.
A motor case 5 is provided on the back side of the blade case 3 so as to protrude rearward. An electric motor 5 a is built in the motor case 5. The blade 4 rotates using the electric motor 5a as a drive source.
A handle 6 for a user to hold is provided on the side of the motor case 5. The handle portion 6 has a generally loop shape straddling the side portion and the upper portion of the motor case 5. The switch 10 of the first embodiment is disposed on the inner peripheral side of the handle portion 6. Details of the switch 10 of the first embodiment are shown in FIGS.
The switch 10 includes a switch lever 11 that a user operates with a fingertip and a switch body 13 including a switch knob 12. The switch lever 11 is positioned in a support hole 6a that opens to the inner peripheral side of the handle portion 6 and is held so as to be movable between an on position and an off position. FIG. 3 shows a state where the switch lever 11 is located at the off position, and FIG. 5 shows a state where the switch lever 11 has moved to the on position. The switch lever 11 is a box-shaped resin molded body that opens upward in the figure, and has a finger pad 11a on the lower surface side. This finger rest 11 a is directed to the inner peripheral side of the handle portion 6.
The switch body 13 is a conventionally known switch body having a bar-shaped switch knob 12 spring-biased to the off position side, and is fixed in the handle portion 6. This switch body 13 is incorporated in the drive circuit of the electric motor 5a. When the switch body 13 is turned on, the electric motor 5a is started, and when the switch body 13 is turned off, the electric motor 5a is stopped. The switch knob 12 of the switch body 13 is supported so as to be movable in the axial direction while protruding from the side of the switch body 13. The switch knob 12 is urged to the off position side (protrusion side) by a knob urging spring 12a incorporated in the switch body 13, and the switch knob 12 is turned on for a certain idling distance L2 from the off position against this urging force. When moving to the position side (retraction side), the switch body 13 is turned on and the electric motor 5a is started.

A lever biasing spring 14 is interposed between the switch knob 12 and the switch lever 11. In this embodiment, a compression coil spring is used for the lever biasing spring 14. The switch urging spring 14 urges the switch lever 11 toward the off position shown in FIG. The urging force of the lever urging spring 14 is set to be smaller than the urging force of the switch knob 11. For this reason, when the switch lever 11 is moved from the off position shown in FIG. 3 to the on position side as shown in FIG. 4, the lever urging spring 14 is first contracted to increase the urging force. , The switch knob 12 does not move from the off position while it moves to the on position side by a fixed distance L1. This fixed distance L1 corresponds to the idle travel distance L1 of the switch lever 11 with respect to the switch knob 12. Further, the sum of the idle running distance L1 and the idle running distance L2 of the switch knob 12 itself corresponds to an embodiment of the idle running distance L described in claim 1, and is formed by the lever biasing spring 14 and this. The idle running distance L1 corresponds to an embodiment of the lever idle running distance providing means.
When the switch lever 11 is moved to the ON position side by the idle travel distance L1 against the lever biasing spring 14, and further moved as it is, the switch knob 11 resists the knob biasing spring 12a as shown in FIG. To move to the ON position. As described above, when the switch knob 11 moves by the idle travel distance L2 against the knob biasing spring 12a, the switch body 13 is turned on and the electric motor 5a is activated. Therefore, according to the switch 10 according to the first embodiment, the switch body 13 is turned on when the switch lever 11 is moved to the on side by the idle travel distance L (= L1 + L2).
Thus, in the switch 10 according to the first embodiment, the idle travel distance L1 of the switch lever 11 with respect to the switch knob 12 is added to the idle travel distance of the switch lever 11 in addition to the idle travel distance L2 of the switch knob 12 itself. For this reason, the idle travel distance is larger than that of the conventional knob-integrated switch lever. For this reason, erroneous operation and malfunction of the switch lever 11 can be prevented more reliably than before without providing a separate lock-off mechanism.
In addition, since the switch body 12 is not configured to change the idle travel distance L2 itself, and the switch body 12 can be used as it is, the idle travel distance L of the switch lever 11 is exemplified. In addition, it is possible to easily change or switch between a type with a large running distance L (a type to which the present embodiment is applied) and a type with a small running distance (conventional type).

Next, the switch 20 of the first related form will be described. Details of the switch 20 in the first related form are shown in FIGS. In the switch 10 of the first embodiment, with respect to the idle travel distance of the switch lever 11, a large idle travel distance L (= L1 + L2) is obtained by providing the idle travel distance L1 between the switch lever 11 and the switch knob 12. It has a configuration. On the other hand, in the switch 20 of the first related form , a large idle travel distance L is set in the switch lever 21 by moving the switch body 23.
The switch 20 of the first related form includes a switch lever 21 and a switch body 23 as in the first embodiment. The switch lever 21 is held so as to be movable between an on position and an off position in a support hole 6 a provided on the inner peripheral surface of the handle portion 6. The switch lever 21 is integrally provided at the tip of the switch knob 22 of the switch body 23. For this reason, when the switch lever 21 is moved, the switch knob 22 moves integrally therewith. This point is in common with the conventional knob-integrated switch lever. The switch knob 22 is urged to the protruding side (off side) by a knob urging spring 22 a built in the switch body 23.
The first related embodiment is greatly different in that the switch main body 23 is movably supported inside the handle portion 6. The switch body 23 is supported so as to be movable in the same direction as the movement direction of the switch lever 21. Two main body biasing springs 25 and 25 are interposed between the back surface of the switch main body 23 and the wall portion 6b of the handle portion 6 facing the back surface. In the first related embodiment , compression springs are used for the main body biasing springs 25 and 25. The switch body 23 is biased downward (switch lever 21 side) in the figure by the body biasing springs 25, 25. The total urging force by the two main body urging springs 25, 25 is set to be smaller than the urging force of the knob urging spring 22a that urges the switch knob 22 to the off position side. For this reason, when the switch lever 21 is pulled from the off position shown in FIG. 6 toward the on position side as shown in FIG. 7, first, the switch body 23 moves upward in the figure against the body biasing springs 25 and 25. fall back. In the first related form , the backward movement of the switch body 23 functions as the idle travel distance L3 of the switch lever 21. As shown in FIG. 7, after the switch body 23 has moved to the retracted end, when the switch lever 21 is further pulled as it is, the switch knob 22 is moved by the idle running distance L2 against the knob biasing spring 22a and turned on. To the position. Therefore, the total (L2 + L3) of the idle travel distance L3 and the idle travel distance L2 of the switch knob 22 itself corresponds to an embodiment of the idle travel distance L described in claim 1, and the main body biasing spring 25 25 and the idle running distance L3 formed thereby correspond to an embodiment of the lever idle running distance providing means.
Thus, the travel distance (idle distance L) of the switch lever 21 required until the switch body 23 is turned on is L2 + L3, and the distance traveled by the switch body 23 (idle distance L3) is larger than the conventional distance. Obtainable. Therefore, according to the switch 20 which concerns on a 1st related form , by setting appropriately the moving distance (idle running distance L3) of the switch main body 23, and the urging | biasing force of the main body urging | biasing springs 25 and 25, fully more than before. A large idling distance can be obtained, thereby preventing erroneous operation and malfunction of the switch lever 21 more reliably than before without providing a separate lock-off mechanism or the like.
In addition, since there is no need to make any changes to the switch body 23 itself according to the first related form , the conventional switch body 23 can be used as it is, and the idle travel distance of the switch lever 21 is large or small. Changes or switching can be easily performed.

Next, the switch 30 according to the second related embodiment will be described. The switches 10 and 20 of the first embodiment and the first related form exemplify the configuration in which the switch levers 11 and 21 are translated, but the switch 30 of the second related form is configured to be tilted rather than translated. This is different from the previous two embodiments.
Details of the switch 30 are shown in FIGS. The switch 30 includes a switch lever 31 and a switch body 33 that are pulled by a user. The switch lever 31 is supported so as to be tiltable via a support shaft 34 provided on the handle portion 6. The switch lever 31 is a resin-molded part including a finger pad portion 31 a and a support arm portion 31 b, and a distal end portion of the support arm portion 31 b is supported by the handle portion 6 via a support shaft 34. A knob pad 31c is integrally provided on the back side (upward in the figure) of the finger pad 31a. The switch knob 32 of the switch body 33 is abutted against the knob abutting portion 31c. The switch knob 32 is urged to the protruding side by a knob urging spring 32 a in the switch body 33. Therefore, the switch knob 32 is abutted against the knob abutting portion 31c of the switch lever 31 by the urging force of the knob urging spring 32a.
The switch knob 32 is a knob abutting portion 31 c and is abutted on the center of the switch lever 31 in the longitudinal direction. For this reason, by the tilting operation of the switch lever 31, the radius R1 of the moving path of the abutting portion with respect to the knob abutting portion 31c of the switch knob 32 is approximately half of the radius R2 of the moving path of the tilting tip portion of the switch lever 31. The degree is (R1 <R2). On the other hand, the switch knob 32 is urged to the protruding side (off position side) by a knob urging spring 32a built in the switch body 33 as in the first embodiment and the first related embodiment . The switch knob 32 itself also has an idle running distance L2 up to the on position.
From this, the idle running distance L4 of the tilting tip of the switch lever 31 is obtained by amplifying the idle running distance L2 of the switch knob 32 by a ratio (R2 / R1), and the idle running distance L2 of the switch knob 32 is approximately the same. It is possible to obtain a free running distance L4 of about twice. By appropriately setting the abutting portion of the switch knob 32 with respect to the knob abutting portion 31c, the idling distance L2 of the switch knob 32 itself can be amplified at an arbitrary ratio to be the idling distance L4. For the switch lever 31, a sufficiently large free running distance L 4 can be obtained. The idling distance L4 corresponds to an embodiment of the idling distance L described in claim 1, and the tilting support structure of the switch lever 31 and the amplification structure of the idling distance L2 of the switch knob 32 realized thereby. This corresponds to one embodiment of the lever idling distance providing means described in claim 1.
Also, in the case of the second related form , since it is not necessary to make any special changes to the switch body 33 itself, it is possible to use the switch body 33 having the conventional configuration having the switch knob 32 with the idle travel distance L2 as it is. In addition, the idle travel distance of the switch lever 31 can be easily changed or switched between a large idle travel distance type and a small idle travel distance type.

Each embodiment described above can be further modified. For example, a configuration in which the first embodiment and the first related embodiment are combined, that is, an idle travel distance L1 is set between the switch lever and the switch knob, and the switch main body is movably supported on the switch support portion of the handle portion. By setting the idle running distance L3, a larger idle running distance can be obtained.
Moreover, although the switch provided in the loop-shaped handle portion 6 has been illustrated, the present invention can be similarly applied to a switch disposed on a straight rod-shaped handle.
Although the switch that the user turns on by pulling with the fingertip is illustrated, the present invention can also be applied to a switch that is turned on by the user pushing with the fingertip or palm.
Although the configuration using the compression coil spring as the lever biasing spring 14, the main body biasing spring 25, and the knob biasing springs 12a, 22a, and 32a is illustrated, it can be replaced with a tension spring or a leaf spring. In addition, other urging means such as a cushion damper may be used instead of the spring.
Furthermore, although the switch 10, 20, 30 for starting the drive motor of the electric tool has been illustrated, for example, it is applied to a switch of various electric devices equipped in the electric tool, such as a switch for lighting fixtures equipped in the electric tool. You can also
In addition, although a portable circular saw has been illustrated as an example of an electric tool, for example, a table-type circular saw, a reciprocating cutting machine such as a reciprocating saw, a rotary tool such as a screwing machine or an electric drill for drilling, etc. It can be widely applied to power tools.

It is the figure which looked at the portable circular saw provided with the switch of 1st Embodiment of this invention from the front side. It is a top view of the portable circular saw provided with the switch of 1st Embodiment of this invention. It is the figure which looked at the switch of a 1st embodiment from the front side. This figure shows a state where the switch lever is located at the OFF position. It is the figure which looked at the switch of a 1st embodiment from the front side. This figure shows a halfway position where the switch lever has been pulled and has been moved to the on position side by the idle running distance L1. It is the figure which looked at the switch of a 1st embodiment from the front side. This figure shows a state where the switch lever is moved to the ON position. In this figure, the OFF position of the switch lever is indicated by a two-dot chain line. It is the figure which looked at the switch of the 1st related form from the front side. This figure shows a state where the switch lever is located at the OFF position. It is the figure which looked at the switch of the 1st related form from the front side. This figure shows a halfway position where the switch lever has been pulled and has been moved to the on position side by the idle running distance L3. It is the figure which looked at the switch of the 1st related form from the front side. This figure shows a state where the switch lever is moved to the ON position. In this figure, the OFF position of the switch lever is indicated by a two-dot chain line. It is the figure which looked at the switch of the 2nd related form from the front side. This figure shows a state where the switch lever is located at the OFF position. It is the figure which looked at the switch of the 2nd related form from the front side. This figure shows a state where the switch lever is moved to the ON position.

1 ... Portable circular saw (power tool)
DESCRIPTION OF SYMBOLS 5 ... Motor case, 5a ... Electric motor 6 ... Handle part, 6a ... Support hole, 6b ... Wall part 10 ... Switch (1st Embodiment)
DESCRIPTION OF SYMBOLS 11 ... Switch lever, 11a ... Finger contact part 12 ... Switch knob, 12a ... Knob energizing spring 13 ... Switch main body L1 ... Free running distance with respect to switch knob of switch lever (1st Embodiment)
L2 ... Distance traveled by switch knob 14 ... Lever biasing spring 20 ... Switch ( first related form )
DESCRIPTION OF SYMBOLS 21 ... Switch lever 22 ... Switch knob, 22a ... Knob energizing spring 23 ... Switch main body 25 ... Main body energizing spring L3 ... Free running distance of switch main body ( 1st related form )
30 ... Switch ( second related form )
31 ... switch lever 32 ... switch knob 32a ... knob biasing spring 33 ... switch body R1 ... moving radius R2 of the knob abutting portion ... moving radius L4 of the lever tip portion ... idle running distance of the switch lever tilting tip portion ( second) Related form )
L: Distance traveled by switch lever

Claims (3)

A switch lever which the user of the power tool is operated to move, and have a empty run distance bar-shaped switch knob leading to L2 only move to ON position to the ON position side by the moving operation to the on position side of the switch lever, A switch comprising a switch body having a knob biasing means for biasing the switch knob at one end in the longitudinal direction of the switch knob ,
A lever idling distance imparting means for making the idling distance L as an operation amount of the switch lever necessary for turning on the switch main body larger than the idling distance L2 of the switch knob is provided on the switch body. Provided outside, the lever idle distance means is provided with a lever urging means between the switch lever and the switch knob, and the switch knob does not move from the off position while the switch lever moves to the on position side by a certain distance. .   2. The switch according to claim 1, wherein the lever idling distance imparting means includes a lever biasing spring that biases the switch lever toward an off position between the switch lever and the switch knob. The switch is configured to have an idle running distance L1 for the operation of moving the switch lever to the ON position side. The switch described in any one of claims 1-2, the power tool having a switch for the electric motor activated as the drive source.

Images