JP2009297804A - Circular saw - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a technique helpful in improving smoothing of cutting operation by smoothly controlling the cutting rate of a saw blade in a circular saw performing cutting operation of a workpiece. <P>SOLUTION: In terms of output characteristics and efficiency characteristics of a blade 113 in a normal use torque range between a minimum torque prescribed based on a minimum depth of cut of the workpiece by the blade 113, and a maximum torque prescribed based on a maximum depth of cut of the workpiece by the blade 113, a transmission mechanism 117 of the circular saw 101 includes a first set mode for forming a first substantially chevron characteristic curve having at least one peak in a range below a medium torque between the minimum torque and the maximum torque, and a second set mode for forming a second substantially chevron characteristic curve having at least one peak in a torque region above the medium torque. <P>COPYRIGHT: (C)2010,JPO&amp;INPIT

Description

  The present invention relates to a technique for constructing a circular saw for cutting a workpiece.

A circular saw for cutting a workpiece is disclosed in, for example, Japanese Patent Application No. 01-99714 (Patent Document 1). The circular saw described in Patent Document 1 has the possibility of changing the cutting speed of the saw blade according to the cutting area of the workpiece, etc., but this kind of circular saw that performs the cutting operation of the workpiece is designed. In this case, a technique is demanded that enables the cutting speed of the saw blade to be smoothly controlled in accordance with the actual cutting work, thereby improving the smoothness of the cutting work.
Japanese Patent Application No. 01-99714

  The present invention has been made in view of the above points, and in a circular saw that performs a cutting operation of a workpiece, a technique that contributes to an improvement in the smoothness of the cutting operation by enabling the cutting speed of the saw blade to be controlled smoothly. The purpose is to provide.

  In order to achieve the above object, a circular saw according to the present invention includes a power source, a saw blade that is rotationally driven to cut a workpiece, and a rotation of the saw blade interposed between the power source and the saw blade. At least a speed change mechanism that makes the speed variable is provided. As the “circular saw” here, a circular saw for woodworking, metalworking, ceramics, or plastic that performs a cutting work of a workpiece by a rotating saw blade can be preferably used. A saw or a table-type circular saw is included in the “circular saw” referred to herein. In addition, the “saw blade” referred to here widely includes a tip saw, a saw blade, a cutting grindstone, a diamond wheel, and the like. The “power source” referred to here typically corresponds to an electric motor, but preferably includes an air motor other than the electric motor, a prime mover such as an engine, and the like.

  In the present invention, in particular, the speed change mechanism is configured to include at least a first setting mode and a second setting mode. The first setting mode relates to the output characteristic or efficiency characteristic of the saw blade in the normal use torque range between the minimum torque and the maximum torque, and is at least 1 in a torque region below the intermediate torque between the minimum torque and the maximum torque. The setting mode forms a first characteristic curve having an approximately mountain shape having two peaks. The second setting mode relates to the output characteristic or efficiency characteristic of the saw blade in the normal use torque range between the minimum torque and the maximum torque, and at least 1 in a torque region exceeding the intermediate torque between the minimum torque and the maximum torque. The setting mode is to form a substantially mountain-shaped second characteristic curve having two peaks. The minimum torque is typically a torque defined based on the minimum cutting depth of the workpiece by the saw blade, and the maximum torque is typically based on the maximum cutting depth of the workpiece by the saw blade. The torque is defined as The torque may be defined not only based on the depth of cut of the workpiece, but also based on the type of the workpiece, how to cut the workpiece (right angle cut, inclined cut, etc.), and the like.

According to such a configuration of the circular saw according to the present invention, by adopting the speed change mechanism including at least the first setting mode and the second setting mode, it is possible to smoothly cope with the fluctuation of the load torque generated during the cutting operation. It is possible to carry out the cutting work. Compared with the speed change mechanism set to only one of the two setting modes, the output and efficiency can be stabilized at a high level, and the first setting particularly at light load. In the mode, it is possible to increase the rotational speed of the saw blade, while in the second setting mode under heavy load, it is possible to set a high torque.
Note that the switching between the first setting mode and the second setting mode may be automatic, which is automatically performed based on actual torque detection information, or by manual operation of the operation member by the operator. It may be performed manually.

  In the circular saw according to a further aspect of the present invention, the speed change mechanism includes a first torque corresponding to a peak of the first characteristic curve in the first setting mode, and a second torque in the second setting mode. Regarding the second torque corresponding to the peak of the characteristic curve, it is preferable that the ratio of the second torque to the first torque be 1.5 to 2.5. According to such a configuration, it is possible to configure a speed change mechanism that is practically highly smooth in speed change operation.

  Moreover, in the circular saw of the further form which concerns on this invention, the said speed change mechanism has a 1st power transmission path | route and a 2nd power transmission path | route. The first power transmission path is configured as a power transmission path for transmitting torque of the input shaft driven by the power source to the output shaft of the saw blade in the first setting mode, and is connected to the input shaft. A gear and a first driven gear engaged with and engaged with the first drive gear and connected to the output shaft. The second power transmission path is configured as a power transmission path for transmitting the torque of the input shaft driven by the power source to the output shaft of the saw blade in the second setting mode, and is a second drive connected to the input shaft. A gear and a second driven gear engaged with and engaged with the second drive gear and connected to the output shaft. In particular, in this speed change mechanism, the second gear ratio relative to the first gear ratio is related to the first gear ratio of the first driven gear to the first drive gear and the second gear ratio of the second driven gear to the second drive gear. It is preferable that the gear ratio is 1.5 to 2.5. According to such a configuration, it is possible to configure a speed change mechanism that is practically highly smooth in speed change operation.

  Moreover, it is preferable that the circular saw of the further form which concerns on this invention is a structure provided with the detection mechanism which detects the torque which acts on a saw blade. The “detection mechanism” referred to here widely includes a mechanical detection mechanism using a spring or the like, or an electrical detection mechanism using a sensor or the like that detects torque continuously or intermittently. In this configuration, the speed change mechanism switches from the first setting mode to the second setting mode when the detected torque exceeds the intermediate torque, based on the detected torque detected by the detecting mechanism, When the torque falls below the intermediate torque, the second setting mode is switched to the first setting mode. According to such a configuration, switching between the first setting mode and the second setting mode can be automatically performed according to the work load, which is reasonable. Typically, in the state where the first setting mode is switched to the second setting mode, the second setting mode is maintained in order to prevent frequent switching around the switching torque. It is preferable to provide a function for

  As described above, according to the present invention, in a circular saw that performs a cutting operation on a workpiece, it becomes possible to improve the smoothness of the cutting operation by enabling the cutting speed of the saw blade to be controlled smoothly. It was.

  Hereinafter, an embodiment of the present invention will be described with reference to the drawings. This embodiment will be described using a rechargeable circular saw (also called a power tool) equipped with a battery as an example of the “circular saw” in the present invention. FIG. 1 is a side view showing the overall configuration of the circular saw 101 according to the present embodiment, FIG. 2 is a side sectional view showing the overall configuration of the circular saw 101, and FIG. 3 shows the overall configuration of the circular saw 101. It is sectional drawing seen from the front. As shown in FIGS. 1 to 3, the circular saw 101 according to the present embodiment is generally a base that is placed on a workpiece (not shown for convenience) and moved in the cutting direction. 111 and a circular saw main body 103 disposed above the base 111.

  The circular saw body 103 accommodates a blade case 104 that covers substantially the upper half of a disk-shaped blade (saw blade) 113 that rotates in a vertical plane, a motor housing 105 that houses a drive motor 115, and a speed change mechanism 117. The gear housing 107 and the handgrip 109 that the operator grips and operates the circular saw 101 are mainly configured. The blade 113 is a saw blade that is rotationally driven to cut the workpiece, and corresponds to the “saw blade” in the present invention, and the drive motor 115 corresponds to the “power source” in the present invention.

  A safety cover 106 that covers the lower half of the blade 113 is rotatably attached to the blade case 104. The lower edge portion of the blade 113 including the safety cover 106 protrudes to the lower surface side through an opening 111a (see FIG. 3) formed in the base 111. When the safety cover 106 is moved forward (rightward in FIGS. 1 and 2) with the front end portion (right side in FIG. 2) of the base 111 placed on the workpiece to cut the workpiece, The front end is pushed by the workpiece and retracted and accommodated in the blade case 104. The handgrip 109 is connected to the upper side of the gear housing 107 and includes a trigger switch 109a that energizes and drives the drive motor 115 by pulling. The blade 113 is rotationally driven via the speed change mechanism 117 when the drive motor 115 is energized. The speed change mechanism 117 here is a mechanism that is interposed between the drive motor 115 and the blade 113 and makes the rotational speed of the blade 113 variable, and corresponds to a “speed change mechanism” in the present invention. A battery 108 is detachably attached to the end of the hand grip 109. The drive motor 115 according to the present embodiment is a motor with a brake, and a rare earth motor is used. Moreover, as the battery 108, it is preferable to use a lithium ion battery of 42 volts or less.

  Next, the speed change mechanism 117 will be described with reference to FIGS. The speed change mechanism 117 according to the present embodiment includes an input shaft 121 coaxially connected to the motor shaft 116 of the drive motor 115, a blade mounting shaft 125 as an output shaft to which the blade 113 is mounted, and the input shaft 121 and the blade mounting shaft. The intermediate shafts 123 arranged between the two are parallel triaxial types arranged parallel to each other, and the power transmission path is automatically changed from high speed low torque to low speed high according to the load acting on the blade 113. It is configured as a two-stage switching type that switches to torque. The input shaft 121 here corresponds to the “input shaft” in the present invention, and the blade mounting shaft 125 here corresponds to the “output shaft” in the present invention. 4 and 5 are developed cross-sectional views of the parallel triaxial transmission mechanism 117. FIG. 4 shows a state where the power transmission path is switched to the high speed and low torque side, and FIG. 5 shows that the power transmission path is the low speed and high torque. The state switched to the side is shown. In the following description, the blade mounting shaft 125 is referred to as an output shaft.

  The transmission mechanism 117 has a first power transmission path in which the torque of the input shaft 121 is transmitted from the pinion gear 131 to the output shaft 125 via the first intermediate gear 132, the intermediate shaft 123, the second intermediate gear 133, and the first driven gear 134. P1 and a second power transmission path P2 in which the torque of the input shaft 121 is transmitted from the pinion gear 131 to the output shaft 125 via the first intermediate gear 132, the intermediate shaft 123, the third intermediate gear 135, and the second driven gear 136. Have. The gear ratio (reduction ratio) between the second intermediate gear 133 and the first driven gear 134 is set smaller than the gear ratio (reduction ratio) between the third intermediate gear 135 and the second driven gear 136. Thus, the first power transmission path P1 is defined as a high-speed and low-torque power transmission path, and the second power transmission path P2 is defined as a low-speed and high-torque power transmission path. The first power transmission path P1 and the second power transmission path P2 are indicated by thick lines with arrows. The first power transmission path P1 here corresponds to the “first power transmission path” in the present invention, and the second power transmission path P2 here is the “second power transmission path” in the present invention. Equivalent to.

  The input shaft 121, the intermediate shaft 123, and the output shaft 125 in the speed change mechanism 117 are rotatably supported by the gear housing 107 via bearings 121a, 123a, and 125a, respectively. A pinion gear 131 as a drive gear is formed integrally with the input shaft 121. The first intermediate gear 132 and the third intermediate gear 135 are arranged in parallel on one end side of the intermediate shaft 123 (on the drive motor 115 side and on the left side in the drawing), and the intermediate shaft 123 via a common key 137. The first intermediate gear 132 is always meshed and engaged with the pinion gear 131, and the third intermediate gear 135 is always meshed with the second driven gear 136 provided on one end side of the output shaft 125. It is set as the structure engaged. The second intermediate gear 133 is attached to the other end side of the output shaft 125 (on the blade 113 side, the right side in the figure) via a bearing 138 and is disposed on the other end side of the output shaft 125. In addition, the first driven gear 134 integrated with the output shaft 125 is always meshed and engaged via the key 139.

  In the circular saw 101 according to the present embodiment, at the initial stage of the cutting operation with a small load acting on the blade 113 during the cutting operation of the workpiece by the blade 113, the output shaft 125, that is, the blade 113 is connected at high speed and low. When the load applied to the blade 113 reaches a certain value or more as the cutting operation progresses, it is automatically switched to the second power transmission path P2 of low speed and high torque. Configured. Such switching from the first power transmission path P1 to the second power transmission path P2 is realized by providing a sliding engagement clutch 141 on the intermediate shaft 123 and a one-way clutch 145 on the output shaft 125. Has been. A specific setting for switching from the first power transmission path P1 to the second power transmission path P2 will be described later with reference to FIGS.

  The structure of the sliding engagement clutch 141 is shown in FIGS. 6 to 10 in addition to FIGS. 6 is an external view of the sliding engagement clutch 141, and FIG. 7 is a cross-sectional view taken along line AA of FIG. 8 shows the drive side clutch member 142, FIG. 9 shows the driven side clutch member 143, and FIG. 10 shows the torque ring 152. As shown in FIG. 6, the sliding engagement clutch 141 includes a driving side clutch member 142 and a driven side clutch member 143 that are arranged opposite to each other in the major axis direction of the intermediate shaft 123, and a driving side clutch member 142. The main component is a clutch spring 144 that presses and urges the driven clutch member 143 toward the driven clutch member 143. As shown in FIGS. 8 and 9, each of the driving side clutch member 142 and the driven side clutch member 143 has a plurality of (for example, three) substantially trapezoidal chevron-shaped cams 142a and 143a on the side surfaces facing each other. The angle cams 142a and 143a mesh with each other to transmit torque (see FIGS. 4 and 6), and the meshing engagement is released to stop torque transmission (FIG. 5). reference).

  The drive side clutch member 142 is fitted to the intermediate shaft 123 in a loose fit. That is, it is slidably attached to the intermediate shaft 123 in the circumferential direction and the long axis direction, and is rotationally driven via a torque ring 152 as a torque transmission member press-fitted and fixed to the intermediate shaft 123. The As shown in FIG. 10, the torque ring 152 includes a plurality of (three) projecting portions 152 a that project in the outer diameter direction at circumferentially equal positions. A housing space 153 having a shape substantially corresponding to the outer shape of the torque ring 152 is formed on the side surface of the drive-side clutch member 142 where the chevron cam 142 a is formed. The torque ring 152 is formed in the housing space 153. It is housed so that it cannot move in the circumferential direction. Therefore, when the torque ring 152 is rotated together with the intermediate shaft 123, the driving side clutch member 142 is in the radial direction of the engagement recess 153a (see FIG. 8) that engages with the protrusion 152a of the torque ring 152 in the accommodation space 153. The wall surface, that is, the torque transmission surface 153b is pressed in the circumferential direction to rotate integrally. On the other hand, the driven clutch member 143 is integrated with the second intermediate gear 133.

  The drive-side clutch member 142 is in a position where the mountain cam 142a is engaged with and engaged with the mountain cam 143a of the driven clutch member 143 by a clutch spring 144 formed of a compression coil spring as an elastic member, that is, power transmission. Energized to position. The clutch spring 144 is arranged in a resilient manner between the drive side clutch member 142 and the first intermediate gear 132.

  In a state where the blade 113 is rotationally driven by the first power transmission path P1, if a load exceeding a certain value exceeding the urging force of the clutch spring 144 acts on the blade 113, the length acting on the slopes of the angle cams 142a, 143a. The driving side clutch member 142 is moved (retracted) in a direction away from the driven side clutch member 143 by the force of the axial component. In other words, the drive-side clutch member 142 is moved to the power release position, the meshing engagement of the angle cams 142a and 143a is released, and the power is cut off. FIG. 11A shows a mode in which the sliding mesh clutch 141 changes from the power transmission state to the power cutoff state. When the sliding engagement clutch 141 is switched to the power cut-off state, the one-way clutch 145 is operated, and the power transmission path is changed from the first power transmission path P1 having high speed and low torque to the second power transmission path P2 having low speed and high torque. Can be switched. The clutch spring 144 here constitutes a detection mechanism for detecting the torque acting on the blade 113, and corresponds to the “detection mechanism” in the present invention.

  Next, the one-way clutch 145 will be described. The configuration of the one-way clutch 145 is shown in FIGS. 15 and 16. 15 is a side view showing each member provided on the output shaft 125, and FIG. 16 is a sectional view taken along the line CC in FIG. The one-way clutch 145 mainly includes an outer ring 146 that rotates together with the second driven gear 136, and a plurality of needle rollers 147 and a spring 148 that are interposed between the outer ring 146 and the output shaft 125. The needle rollers 147 are rotatably disposed in cam grooves 146a formed at a predetermined interval in the circumferential direction of the outer ring 146, and are urged toward the meshing position of the cam surface 146b by a spring 148.

  Accordingly, when the outer ring 146 is rotated clockwise in FIG. 16 with respect to the output shaft 125 together with the first driven gear 134, the needle roller 147 is moved between the cam surface 146b and the output shaft 125 by the biasing force of the spring 148. The output shaft 125 is driven by biting and wedge action. This state is shown in FIG. On the other hand, when the output shaft 125 rotates at a higher speed than the outer ring 146, the outer ring 146 rotates relative to the output shaft 125 counterclockwise in the figure. For this reason, the needle rollers 147 are separated from the cam surface 146 b, and the outer ring 146 is idled with respect to the output shaft 125. That is, when the sliding engagement clutch 141 is in the power transmission state, the outer ring 146 is rotated counterclockwise in the drawing relative to the output shaft 125, so that the one-way clutch 145 runs idle and does not transmit power.

  According to the speed change mechanism 117 configured as described above, when the drive motor 115 is stopped, the sliding mesh clutch 141 is moved closer to the driven clutch member 143 by the urging force of the clutch spring 144. It has been moved to the side. In other words, the angle cams 142a and 143a of both clutch members 142 and 143 are held in a power transmission state in which the clutches 142a and 143a mesh with each other. In this state, when the drive motor 115 is energized to cut the workpiece, the torque of the drive motor 115 is transmitted to the output shaft 125 via the first power transmission path P1. That is, the blade 113 is driven to rotate at high speed and low torque through the pinion gear 131, the first intermediate gear 132, the intermediate shaft 123, the sliding mesh clutch 141, the second intermediate gear 133, the first driven gear 134, and the output shaft 125. The

  At this time, the outer ring 146 of the one-way clutch 145 is also rotated from the intermediate shaft 123 via the third intermediate gear 135 and the second driven gear 136. However, as described above, the rotational speed of the output shaft 125 is higher than the rotational speed of the outer ring 146. Is high speed, the outer ring 146 rotates idly.

  As described above, the work for cutting the workpiece by the blade 113 starts at high speed and low torque using the first power transmission path P1. When the cutting operation progresses and the load acting on the blade 113 exceeds the switching set value set by the clutch spring 144 of the sliding mesh clutch 141, the sliding mesh clutch 141 is switched to the power cut-off state. Change. That is, as shown in FIG. 11A, the drive-side clutch member 142 has a long-axis direction component acting on the drive-side clutch member 142 via the cam surfaces (slopes) of the angle cams 142a and 143a. The clutch is separated from the driven clutch member 143 against the urging force, and the meshing engagement of the angle cams 142a and 143a is released. Thus, when the sliding engagement clutch 141 is switched to the power cut-off state and the rotation speed of the output shaft 125 falls below the rotation speed of the outer ring 146 of the one-way clutch 145, the needle roller 147 is caused to come into contact with the cam surface 146b by the biasing force of the spring 148. And the output shaft 125, and the output shaft 125 is driven by a wedge action. As a result, the torque transmission path of the drive motor 115 is switched from the first power transmission path P1 to the second power transmission path P2, and the blade 113 has the gear ratio between the pinion gear 131 and the first intermediate gear 13 and the third intermediate gear. 135 and the second driven gear 136 are driven to rotate at a low speed and a high torque determined by the gear ratio.

As described above, according to the present embodiment, when the load acting on the blade 113 is small, the workpiece is cut at high speed and low torque using the first power transmission path P1 having a small reduction ratio. On the other hand, in a state where a large load is applied to the blade 113, the cutting operation can be performed at low speed and high torque using the second power transmission path P2 having a large gear ratio.
As described above, the torque transmission path is automatically switched from the high-speed and low-torque first power transmission path P1 to the low-speed and high-torque second power transmission path P2 according to the load acting on the blade 113. Compared with a circular saw that does not have a speed change mechanism, the drive motor 115 can be prevented from burning and the amount of cutting work per charge of the battery 108 can be improved.

  In particular, in the present embodiment, the second power is transmitted from the first power transmission path P1 in a state where the meshing engagement of each gear in the gear train constituting the transmission mechanism 117 is maintained, that is, the position of each gear is fixed. Since the transmission path P2 can be switched, the speed change operation can be performed smoothly, and the smoothness of the speed change operation can be improved.

  In addition, according to the present embodiment, since the sliding engagement clutch 141 is provided on the intermediate shaft 123 and the one-way clutch 145 is provided on the output shaft 125, the operation of the sliding engagement clutch 141 is controlled. Only by this, switching of the use transmission path from the first power transmission path P1 to the second power transmission path P2 is realized, and a rational speed change mechanism 117 can be constructed.

Further, in this embodiment, since the sliding engagement clutch 141 is provided on the intermediate shaft 123 that rotates at a higher speed and lower torque than the output shaft 125, the load acting on the sliding engagement clutch 141 can be reduced. This is effective in improving the protection or durability of the clutch. Further, the intermediate shaft 123 is disposed closer to the center of the gear housing 107 when viewed from the arrangement of the shafts with respect to the gear housing 107. For this reason, it is possible to suppress an increase in the size of the gear housing 107 by disposing the sliding engagement clutch 141 that is larger in the radial direction than the one-way clutch 145 on the intermediate shaft 123.
By the way, the maximum cutting depth of the circular saw 101 (the amount of protrusion of the lower edge portion of the blade 111 from the lower surface of the base 111) is determined by the operator pressing the handgrip 109 downward in FIG. When the rotary shaft set at the front end of the base 111 is turned around a turning fulcrum (not shown for convenience), the maximum cutting depth provided in the gear housing 107 is omitted for the sake of convenience. Is regulated by abutting against the stopper of the base 111. Therefore, for example, when the sliding engagement clutch 141 having a large outer diameter is provided on the output shaft 125, the distance from the center of the output shaft 125 to the lower end surface 107L of the gear housing 107 increases, which affects the maximum cutting ability. To do. That is, although the maximum cutting ability is reduced, according to the present embodiment, since the sliding engagement clutch 141 is provided on the intermediate shaft 123, the output shaft 125 to the lower end surface 107L of the gear housing 107 are provided. Since the distance can be set small, the maximum cutting ability is not affected.

  On the other hand, the one-way clutch 145 is provided on the output shaft 125. The second driven gear 136 on the output shaft 125 on the deceleration side is set to have a larger diameter than the third intermediate gear 135 on the intermediate shaft 123. Therefore, by providing the one-way clutch 145 between the output shaft 125 and the second driven gear 136, it is easy to secure an arrangement space for the one-way clutch 145, and the one-way clutch 145 can be easily incorporated. .

  By the way, when the sliding engagement clutch 141 is automatically switched according to the load applied to the blade 113, the load applied to the blade 113 fluctuates around the switching set value set by the clutch spring 144. The sliding engagement clutch 141 is frequently switched. Therefore, in order to solve such a problem, the speed change mechanism 117 according to the present embodiment includes a latch mechanism that holds the switched engagement clutch 141 after the sliding engagement clutch 141 is once switched to the power cut-off state, and a disconnection mechanism. After the work is stopped (when the drive motor 115 is stopped), a reset mechanism for returning to the initial state, that is, the power transmission state is provided.

  Hereinafter, the latch mechanism 151 will be described mainly with reference to FIGS. 7, 8, 10, and 11. When the drive side clutch member 142 in the sliding engagement clutch 141 moves to the power cut-off position, the latch mechanism 151 moves the drive-side clutch member 142 to the power cut-off position, more specifically, the angle cam 142a of the drive-side clutch member 142. Is provided as a mechanism for holding the driven side clutch member 143 at a position separated from the angle cam 143a (position facing the gap). The latch mechanism 151 is composed mainly of the torque ring 152 described above.

  In the accommodation space 153 of the drive side clutch member 142 formed to accommodate the torque ring 152, the forward direction of the engaging recess 153a with which the protrusion 152a of the torque ring 152 engages is upwardly inclined. A slope 153c is formed which is inclined at. Then, when the drive-side clutch member 142 moves from the power transmission position to the power cut-off position side to be in the power cut-off state, the torque ring 152 escapes from the accommodation space 153 and rides on the slope 153c. The angle cam 142 a of the clutch member 142 is configured to be separated from the angle cam 143 a of the driven clutch member 143. The operation mode at this time is shown in FIG. 11A shows the operation of the clutch, and FIG. 11B shows the operation of the torque ring 152 as a latch member. In addition, in order to smooth the riding on the inclined surface 153c of the protrusion 152a of the torque ring 152, the surface of the protrusion 152a facing the inclined surface 153c is formed as an inclined surface or an arcuate curved surface.

  As shown in the uppermost stage of FIG. 11, in the meshed engagement state of the angle cams 142a, 143a with the driving side clutch member 142 placed at the power transmission position, the protrusion 152a of the torque ring 152 is engaged with the engagement recess as described above. It is engaged with the torque transmission surface 153b of 153a and held in a torque transmission state. In such a state, when a load greater than a certain value set by the clutch spring 144 acts on the blade 113 and the drive side clutch member 142 moves backward toward the power cut-off position, the torque ring fixed to the intermediate shaft 123 152 moves relative to the drive-side clutch member 142 in the long axis direction, that is, in the direction of exiting (raising) from the accommodation space 153. As a result, when the protrusion 152a of the torque ring 152 comes out of the engagement recess 153a and is disengaged from the torque transmission surface 153b, a rotational speed difference is generated between the drive side clutch member 142 and the torque ring 152 that have received no torque. For this reason, the torque ring 152 moves relative to the drive side clutch member 142 in the circumferential direction, and the protrusion 152a of the torque ring 152 rides on the end of the inclined surface 153c (see the second step from the top in FIG. 11). The drive-side clutch member 142 is pushed in the major axis direction by the riding-up operation of the protrusion 152a. That is, a force is applied to the driving side clutch member 142 in a direction (long axis direction) in which the angle cam 142a is separated from the angle cam 143a of the driven clutch member 143, thereby assisting the separation of the angle cams 142a, 143a. . As a result, the load acting on the cam surfaces of the angle cams 142a and 143a is reduced. This makes it possible to reduce the wear of the angle cams 142a and 143a, and as a result, fluctuations in the switching set value set by the clutch spring 144 can be suppressed.

When the drive side clutch member 142 further moves backward and the engagement of the angle cams 142a and 143a is released, the torque ring 152 further moves relative to the drive side clutch member 142 in the circumferential direction. For this reason, the protrusion 152a further rides on the slope 153c. That is, the assist of separating the angle cams 142a and 143a by the riding is continued even after the engagement of the angle cams 142a and 143a is released. As a result, the drive-side clutch member 142 is further separated from the driven-side clutch member 143, and a gap in the major axis direction is generated between the angle cams 142a and 143a. The protrusion 152a that rides on the slope 153c is engaged with a stopper surface 153d that stands upright in front of the slope 153c, and then the torque ring 152 and the drive-side clutch member 142 rotate together. This state is shown in the lowermost part of FIG.
That is, when the driving side clutch member 142 is switched from the power transmission state to the power cutoff state, the torque ring 152 is a power that causes the angle cam 142a of the driving side clutch member 142 to be separated from the angle cam 143a of the driven side clutch member 143. The position is moved further backward than the blocking position, that is, moved to an isolation position where a predetermined gap in the major axis direction is ensured between the angle cams 142a and 143a and held at the isolation position. Thus, once the sliding mesh clutch 141 is switched to the power cut-off side, the power cut-off state is maintained regardless of the load applied to the blade 113 thereafter, so that the load applied to the blade 113 is applied to the clutch spring 144. Even when the change occurs around the switching set value set in the above, it is possible to perform a stable cutting operation at low speed and high torque using the second power transmission path P2. In addition, since the drive-side clutch member 142 is moved to the isolated position and held in the isolated position, a certain gap is secured in the major axis direction between the angle cams 142a and 143a, so that a reliable power cut-off state Thus, abnormal noise or vibration due to the contact of the angle cams 142a and 143a can be prevented.

  On the other hand, when the energization drive of the drive motor 115 is stopped after the cutting operation, the brake of the drive motor 115 is activated. As a result, a rotational speed difference occurs between the torque ring 152 that rotates integrally with the intermediate shaft 123 whose rotational speed is decelerated, and the drive-side clutch member 142 that attempts to maintain the rotational speed by inertia torque. Rotate relative to the direction. The relative rotation in the circumferential direction is a direction in which the protrusion 152a of the torque ring 152 descends from the inclined surface 153c of the drive side clutch member 142. For this reason, the protrusion 152 c is fitted into the engagement recess 153 a of the accommodation space 153. That is, the torque ring 152 is returned (reset) to the initial position, and thereby, the holding of the power cut-off state of the sliding engagement clutch 141 is automatically released. That is, a reset mechanism using the brake of the drive motor 115 and the inertia of the drive side clutch member 142 is configured. When the power cut-off state holding by the torque ring 152 is released, the drive-side clutch member 142 is moved to the power transmission position by the urging force of the clutch spring 144 to prepare for the next cutting operation.

  In the case of the speed change mechanism 117 according to the present embodiment, when the drive motor 115 is activated, if the mass of the blade 113 is large and the inertia is large, the sliding engagement clutch 141 malfunctions, that is, the power transmission state is changed to the power cutoff state. There is a possibility of shifting to. In order to solve such a problem, the speed change mechanism 117 according to the present embodiment includes a speed change restriction mechanism 161 that restricts the speed change at the time of activation.

  Hereinafter, the shift restriction mechanism 161 will be described mainly with reference to FIGS. 12 is a cross-sectional view taken along line BB in FIG. 6, FIG. 13 is a perspective view of the drive side clutch member 142 viewed from the clutch spring mounting side, and FIG. 14 is a perspective view of the stopper 162. The shift restriction mechanism 161 according to the present embodiment is mainly configured by a plurality of (for example, three) stoppers 162 radially arranged on the drive side clutch member 142 and a compression coil spring 163 as an elastic member.

  Each stopper 162 and compression coil spring 163 are housed in a stopper housing recess 164 formed at a circumferentially equal position on the side of the clutch spring mounting surface side (opposite to the angle cam 142a) of the drive side clutch member 142, and in the radial direction. It can be moved. Each stopper 162 has a distal end on the inner diameter side opposed to the outer peripheral surface of the intermediate shaft 123 and is pressed and urged toward the intermediate shaft 123 by a compression coil spring 163. On the outer peripheral surface of the intermediate shaft 123, a circumferential annular groove 165 is formed in a region facing the stopper 162. When the driving side clutch member 142 is placed at the power transmission position, the distal end portion in the radial direction of each stopper 162 enters the annular groove 165 on the outer periphery of the intermediate shaft 123 from the radial direction and is engaged in a resilient manner. Accordingly, the driving side clutch member 142 is held at the power transmission position. This state is shown in FIGS.

  The compression coil spring 163 is stabilized in operation by a guide pin 166 provided on the stopper 162. Further, as shown in FIGS. 4 and 5, a cover member 167 that covers the stopper 162 and the compression coil spring 163 housed in the stopper housing recess 164 is attached to the side surface of the drive side clutch member 142. Also, it functions as a spring receiving member that supports one end of the clutch spring 144.

  The shift restriction mechanism 161 according to the present embodiment is configured as described above. When the drive motor 115 is stopped, the sliding engagement clutch 141 is in a power transmission state. For this reason, the stopper 162 is engaged with the annular groove 165 of the intermediate shaft 123. Accordingly, when the drive motor 115 is started, the movement of the drive side clutch member 142 in the long axis direction is restricted by the stopper 162 that engages with the annular groove 165 of the intermediate shaft 123, and the drive side clutch member 142. Is held at a power transmission position where the angle cam 142a meshes with and engages with the angle cam 143a of the driven side clutch member 143. Thereby, the malfunctioning of the sliding mesh clutch 141 at the time of starting the motor can be prevented.

  Thus, when the drive motor 115 is activated and the rotational speed is increased, the stopper 162 is moved outward against the urging force of the compression coil spring 163 by the centrifugal force acting on the stopper 162 rotating together with the drive side clutch member 142. It moves and escapes from the annular groove 165 (see FIG. 5). As a result, the movement restriction by the stopper 162 of the drive side clutch member 142 is released, and switching from the power transmission state to the power cut-off state according to the load applied to the blade 113 of the drive side clutch member 142 is allowed.

  As described above, according to the speed change restriction mechanism 161 according to the present embodiment, in the circular saw 101 having a large inertia of the blade 113, a malfunction occurs in which the speed change mechanism 117 shifts due to the inertia of the blade 113 when the drive motor 115 is started. Thus, the advantage of the speed change mechanism 117 can be fully utilized. Further, such a speed regulation mechanism 161 is not limited to the circular saw 101, and the mass of the tip tool is large, such as a grinder used for polishing and grinding work and a diamond core drill used for drilling a relatively large diameter. This is particularly effective for power tools.

  During a cutting operation at a low speed and a high torque, an excessive load may act on the blade 113. Therefore, a torque limiter 154 is set on the output shaft 125 in preparation for such an excessive load. FIG. 17 shows a state where the torque limiter 154 is assembled to the output shaft 125. The output shaft 125 is divided into two in the major axis direction into a base side shaft portion 125A to which the first and second driven gears 134 and 136 are attached and a tip side shaft portion 125B to which the blade 113 is attached. They are connected by a torque limiter 154 interposed in the divided part.

  The base-side shaft portion 125A and the distal-end-side shaft portion 125B of the output shaft 125 are arranged coaxially via a circular protrusion and a circular recess that are fitted in a loosely fitting manner, and have flanges 125Aa and 125Ba that face each other. I have. The torque limiter 154 applies a biasing force in a direction in which the friction plate 155 sandwiched between the flange portion 125Aa of the base side shaft portion 125A and the flange portion 125Ba of the distal end side shaft portion 125B and the both flange portions 125Aa and 125Ba are pressed against each other. And a maximum transmission torque is determined by the plate spring 156.

  In this way, since the maximum transmission torque is managed by the torque limiter 154 on the output shaft 125 which is the final shaft, when an excessive load is applied to the blade 113 during the cutting operation, the friction plate 155 becomes the flange portion. An excessive load can be accommodated by sliding against 125Aa and 125Ba.

  In the above-described embodiment, it is also possible to employ a configuration in which the sliding engagement clutch 141 is provided on the output shaft 125 and the speed change is performed on the output shaft 125. 18 and 19 are referred to regarding this configuration. Other than this configuration, the configuration is the same as in the above-described embodiment. 18 and FIG. 19 are given the same reference numerals, and descriptions thereof are omitted or simplified. 18 and 19 are developed sectional views showing the structure of the speed change mechanism 117. FIG.

The sliding engagement clutch 141 is mounted on the output shaft 125. With such an arrangement, the second intermediate gear 133 arranged on the intermediate shaft 123 is fixed to the intermediate shaft 123 by the key 139, and the first intermediate gear 133 is always engaged with and engaged with the second intermediate gear 133. The driven gear 134 is rotatably supported on the output shaft 125 via a bearing 138.
The sliding engagement clutch 141 is composed mainly of the driving side clutch member 142, the driven side clutch member 143, and the clutch spring 144 as in the case of the first embodiment described above. The power transmission direction is reversed from the case of the first embodiment configured to be disposed on the intermediate shaft 123. That is, the clutch member 143 that rotates together with the first driven gear 134 is the driving side, and the clutch member 142 that rotates together with the output shaft 125 via the torque ring 152 is the driven side. The clutch spring 144 is interposed between the driven-side clutch member 142 and the second driven gear 136 to which the one-way clutch 145 is assembled, and biases the driven-side clutch member 142 in the direction in which the driven-side clutch member 142 approaches the driving-side clutch member 143. is doing.

  Therefore, when the load applied to the blade 113 is small, the torque of the drive motor 115 is such that the pinion gear 131 of the input shaft 121, the first intermediate gear 132, the intermediate shaft 123, the second intermediate gear 133, the first driven gear 134, the sliding gear. The power is transmitted to the blade 113 via the first power transmission path P1 constituted by the dynamic meshing clutch 141 and the output shaft 125, and the blade 113 is driven to rotate at high speed and low torque. This state is shown in FIG.

  When a load exceeding the switching set value determined by the clutch spring 144 is applied to the blade 113, the driven clutch member 142 is moved from the power transmission position to the power cutoff position against the clutch spring 144. As a result, the angle cam 142a of the driven clutch member 142 is separated from the angle cam 143a of the drive side clutch member 143, and the meshing engagement is released. Then, the torque of the drive motor 115 is constituted by the pinion gear 131, the first intermediate gear 132, the intermediate shaft 123, the third intermediate gear 135, the second driven gear 136, the one-way clutch 145, and the output shaft 125 of the input shaft 121. The power is transmitted to the blade 113 via the second power transmission path P2, and the blade 113 is driven to rotate at low speed and high torque. This state is shown in FIG.

  Even in such a configuration, as in the above-described embodiment, the first power transmission path is maintained in a state where the meshing engagement of each gear in the gear train constituting the transmission mechanism 117 is maintained, that is, in a state where the position of each gear is fixed. Since it is possible to switch from P1 to the second power transmission path P2, it is possible to smoothly perform the speed change operation and improve the smoothness of the speed change operation.

  Here, the specific setting of switching between the first power transmission path P1 and the second power transmission path P2 in the transmission mechanism 117 configured as described above will be described in detail below. In this setting, at least the first setting mode and the second setting mode can be formed by appropriately selecting a gear combination. The first setting mode here corresponds to the “first setting mode” in the present invention, and the second setting mode here corresponds to the “second setting mode” in the present invention.

The first setting mode is defined as a setting mode (high speed-low torque mode) in which the torque of the blade 113 is relatively low and the rotational speed is relatively high. On the other hand, the second setting mode is defined as a setting mode (low speed-high torque mode) in which the torque of the blade 113 is relatively high and the rotational speed is relatively low. For typical examples of the first setting mode and the second setting mode, FIGS. 20 to 22 are referred to. Here, FIG. 20 shows a correlation graph between the torque [N · m] and the rotation speed [min ⁻¹ ] related to the rotation of the blade 113 of the drive motor 115 of the present embodiment, and FIG. A correlation graph between the torque [N · m] and the output [W] related to the rotation of the blade 113 of the drive motor 115 of the embodiment is shown, and FIG. 22 shows the blade 113 of the drive motor 115 of the present embodiment. Is a correlation graph between the torque [N · m] and the efficiency [%] related to the rotation of.

  As shown in FIG. 20, in the first setting mode, regarding the rotational speed characteristics of the blade 113 in the normal use torque range ΔT between the minimum torque TL and the maximum torque TH, between the minimum torque TL and the maximum torque TH. A first rotational speed characteristic line S1 is formed in a torque region below the intermediate torque TM. On the other hand, in the second setting mode, regarding the rotational speed characteristic of the blade 113 in the normal use torque range ΔT between the minimum torque TL and the maximum torque TH, the second rotational speed characteristic straight line in the torque region exceeding the intermediate torque TM. S2 is formed. The second rotational speed characteristic line S2 is formed continuously from the first rotational speed characteristic line S1. In other words, in the present embodiment, the characteristic straight line related to the rotational speed is switched between a light load (also referred to as “low load”) and a heavy load (also referred to as “high load”) with the intermediate torque TM as a boundary. Is set as follows. In such a rotation speed setting, it is possible to obtain a high rotation state as compared with the case where only one of the rotation speed characteristic lines is used, and in particular, it is possible to increase the rotation speed at a light load. The minimum torque TL, the maximum torque TH, and the intermediate torque TM here correspond to the “minimum torque”, “maximum torque”, and “intermediate torque” in the present invention, respectively.

  Further, as shown in FIG. 21, in the first setting mode, regarding the output characteristics of the blade 113 in the normal use torque range ΔT between the minimum torque TL and the maximum torque TH, between the minimum torque TL and the maximum torque TH. The first output characteristic curve C1 having a substantially mountain shape having one peak (in the case of FIG. 21, the output between the minimum torque TL and the intermediate torque TM) is formed in the torque region below the intermediate torque TM. On the other hand, in the second setting mode, regarding the output characteristics of the blade 113 in the normal use torque range ΔT between the minimum torque TL and the maximum torque TH, there is one peak in the torque region exceeding the intermediate torque TM (in the case of FIG. 21). , And an output corresponding to the maximum torque TH). The second output characteristic curve C2 is formed continuously from the first output characteristic curve C1. That is, in the present embodiment, the characteristic curve relating to the output is set to be switched between the light load and the heavy load with the intermediate torque TM as a boundary. Here, the minimum torque TL is defined based on the minimum cutting depth of the workpiece by the blade 113, and the maximum torque TH is defined based on the maximum cutting depth of the workpiece by the blade 113. . Further, the intermediate torque TM can be defined as a predetermined value or a predetermined numerical range by setting the urging force of the clutch spring 144. In such an output setting, a high output state can be stably obtained as compared with the case where only one of the output characteristic curves is used. The torque may be defined not only based on the depth of cut of the workpiece, but also based on the type of the workpiece, how to cut the workpiece (right angle cut, inclined cut, etc.), and the like.

  Further, as shown in FIG. 22, in the first setting mode, regarding the efficiency characteristic of the blade 113 in the normal use torque range ΔT between the minimum torque TL and the maximum torque TH, between the minimum torque TL and the maximum torque TH. The first efficiency characteristic curve C3 having a substantially mountain shape having one peak (in the case of FIG. 22, the efficiency between the minimum torque TL and the intermediate torque TM) is formed in the torque region below the intermediate torque TM. On the other hand, in the second setting mode, regarding the efficiency characteristic of the blade 113 in the normal use torque range ΔT between the minimum torque TL and the maximum torque TH, there is one peak in the torque region exceeding the intermediate torque TM (in the case of FIG. 22). , An efficiency between the intermediate torque TM and the maximum torque TH) is formed. The second efficiency characteristic curve C4 is formed continuously from the first efficiency characteristic curve C3. That is, in the present embodiment, the characteristic curve relating to efficiency is set to be switched between a light load and a heavy load with the intermediate torque TM as a boundary. In such an efficiency setting, a high efficiency state can be stably obtained as compared with the case where only one of the efficiency characteristic curves is used. Especially in the second setting mode under heavy load, it can be set to a gear ratio that generates a large torque, so that it is possible to prevent locking when using a large blade with heavy load. Can be installed.

  According to such a setting in the speed change mechanism 117 of the present embodiment, at least two setting modes are provided according to the load torque applied to the output shaft 125, so as to cope with fluctuations in the load torque generated during the cutting operation. It is possible to smoothly perform the cutting operation, and therefore it is possible to improve the smoothness of the cutting operation. Further, when compared with the speed change mechanism set to only one of the two setting modes, the output and the efficiency can be stabilized at a high level. In the setting mode, the rotation speed of the blade 113 can be increased, while in the second setting mode under heavy load, it can be set to a gear ratio that generates a large torque, and a large-diameter blade is mounted. It becomes possible. Thereby, the maximum cutting ability can be improved.

  As a specific effect, in the case of a circular saw using only a battery, it is possible to improve the amount of work or shorten the work time by stabilizing the efficiency at a high level, and to reduce the torque. Even a thin DC machine can have a feeling of use like an AC machine. In the case of a circular saw using a battery (DC) and an AC power supply, the output is stabilized at a high level, thereby reducing the number of times the blade 113 is locked under heavy load or reducing the lock torque value. In addition, the current consumption can be reduced and the drive motor 115 can be prevented from being burned out and the battery overcurrent can be protected. Moreover, it becomes possible to improve a cutting speed by the optimal setting according to material. Furthermore, it is possible to perform fine cutting by increasing the peripheral speed of the blade 113, and thus it is possible to improve the cut surface (burrs, surface roughness).

  In the present invention, another setting mode may be set in addition to the first setting mode and the second setting mode of the present embodiment. In the first setting mode and the second setting mode, an approximately chevron-shaped output characteristic curve having at least one peak is formed as necessary, and an approximately chevron-shaped efficiency characteristic having at least one peak. It is possible to set so that a curve is formed.

  Moreover, in the speed change mechanism 117 of the present embodiment, the first torque corresponding to the peak of the first output characteristic curve C1 in the first setting mode and the peak of the second output characteristic curve C2 in the second setting mode. It is preferable to adopt a setting in which the ratio of the second torque to the first torque is 1.5 to 2.5. Similarly, regarding the first torque corresponding to the peak of the first efficiency characteristic curve C3 in the first setting mode and the second torque corresponding to the peak of the second efficiency characteristic curve C4 in the second setting mode, It is preferable to adopt a setting in which the ratio of the second torque to the first torque is 1.5 to 2.5. In the transmission mechanism 117 of the present embodiment, the first gear is related to the first gear ratio of the first driven gear 134 to the second intermediate gear 133 and the second gear ratio of the second driven gear 136 to the third intermediate gear 135. It is preferable to adopt a setting in which the ratio of the second gear ratio to the ratio is 1.5 to 2.5. Here, the second intermediate gear 133, the first driven gear 134, the third intermediate gear 135, and the second driven gear 136 are respectively referred to as “first driving gear”, “first driven gear”, “first driven gear” in the present invention. Corresponds to “second driving gear” and “second driven gear”. According to such settings regarding the torque and the gear ratio, it is possible to configure a transmission mechanism that is practically highly smooth in shifting operation.

  Note that the switching between the first setting mode and the second setting mode is performed by a mechanical detection mechanism using the clutch spring 144 as in the above-described embodiment, or by an electric sensor or the like that detects torque continuously or intermittently. It may be an automatic type that is automatically performed based on actual detection information by a typical detection mechanism, or may be a manual type that is performed by manual operation of an operation member by an operator. In the above embodiment, the case where the second setting mode is held via the latch mechanism 151 has been described. However, when the latch mechanism 151 is omitted, the second setting mode is changed when the detected torque exceeds the intermediate torque. While the setting mode is switched from the first setting mode to the second setting mode, the second setting mode is switched to the first setting mode when the detected torque falls below the intermediate torque.

  Further, although the transmission mechanism 117 according to the present embodiment has been described in the case of the three-axis parallel type, the transmission mechanism 117 is also applicable to a two-axis type constituted by two parallel axes of an input shaft and an output shaft. The one-way clutch 145 is also provided on the intermediate shaft 123 side. Moreover, although this Embodiment demonstrated in the case of the rechargeable circular saw 101, it is not restricted to this. A circular saw that uses an AC power supply instead of a battery, or a hand-held type as shown in the figure, or a tabletop circle that performs cutting work by placing the workpiece on a table installed on the base It can be applied to saws and tabletop slide circular saws, and can be applied to any of woodworking, metalworking, ceramics and plastics. In this case, a saw blade, a saw blade, a cutting grindstone, a diamond wheel, or the like can be used as the saw blade.

It is a side view showing the whole circular saw composition concerning a 1st embodiment of the present invention. It is a sectional side view which shows the whole structure of a circular saw. It is sectional drawing seen from the front which shows the whole structure of a circular saw. FIG. 4 is a developed cross-sectional view of a parallel three-axis transmission mechanism, showing a state where the power transmission path is switched to the high speed and low torque side. FIG. 4 is a developed cross-sectional view of a parallel three-axis transmission mechanism, showing a state where the power transmission path is switched to the low speed and high torque side. It is an external view of a sliding mesh clutch. It is the sectional view on the AA line of FIG. It is a perspective view which shows the drive side clutch member in a sliding type engagement clutch. It is a perspective view of the driven side clutch member in a sliding type engagement clutch. It is a perspective view which shows the torque ring in a sliding engagement clutch. It is a figure explaining operation | movement of a sliding mesh clutch, (A) shows the operation | movement aspect of a chevron cam, (B) shows the operation | movement aspect of the torque ring as a latch member. It is the BB sectional view taken on the line of FIG. It is the perspective view which looked at the drive side clutch member from the clutch spring mounting side. It is a perspective view which shows a stopper. It is a side view which shows each member provided in the output shaft. It is CC sectional view taken on the line of FIG. It is an expanded sectional view showing a modification. It is an expanded sectional view showing a parallel triaxial transmission mechanism concerning another embodiment of the present invention, and shows the state where a power transmission path was switched to the high speed low torque side. FIG. 6 is a developed cross-sectional view showing a parallel triaxial transmission mechanism, showing a state where the power transmission path is switched to the low speed and high torque side. The correlation graph of torque [N * m] and rotation speed [min < ^-1 >] concerning rotation of the blade 113 of the drive motor 115 of this Embodiment is shown. The correlation graph of torque [N * m] and output [W] concerning rotation of blade 113 of drive motor 115 of an embodiment is shown. The correlation graph of torque [N * m] and efficiency [%] concerning rotation of blade 113 of drive motor 115 of this embodiment is shown.

Explanation of symbols

101 Circular saw 103 Circular saw body (Power tool body)
104 Blade case 105 Motor housing 106 Safety cover 107 Gear housing 107L Lower end surface 108 Battery 109 Hand grip 109a Trigger 111 Base 111a Opening 113 Blade 115 Drive motor (power source)
116 Motor shaft 117 Transmission mechanism 121 Input shaft 121a Bearing 123 Intermediate shaft (first rotating shaft)
123a bearing 125 output shaft (second rotating shaft)
125a Bearing 125A Base side shaft portion 125B Tip side shaft portion 125Aa 鍔 portion 125Bb 鍔 portion 131 Pinion gear 132 First intermediate gear 133 Second intermediate gear 134 First driven gear 135 Third intermediate gear 136 Second driven gear 137 Key 138 Bearing 139 Key 141 Sliding mesh clutch 142 Driving clutch member 142a Angle cam 143 Driven clutch member 143a Angle cam 144 Clutch spring 145 One-way clutch 146 Outer ring 146a Cam groove 146b Cam surface 147 Needle roller 148 Spring 151 Latch mechanism 152 Torque ring 152a Protruding portion 153 Housing space 153a Engaging recess 153b Torque transmission surface 153c Slope 153d Stopper surface 154 Torque limiter 155 Friction plate 156 Leaf spring 161 Shift restriction mechanism 162 Stopper 163 Compression Coil spring 164 Stopper receiving recess 165 Annular groove 166 Guide pin 167 Cover member

Claims (4)

A circular saw having a power source, a saw blade that is rotationally driven to cut a workpiece, and a speed change mechanism that is interposed between the power source and the saw blade to vary the rotational speed of the saw blade. There,
The speed change mechanism includes a minimum torque defined based on a minimum cutting depth of the workpiece by the saw blade and a maximum torque defined based on a maximum cutting depth of the workpiece by the saw blade. The first characteristic curve having a substantially chevron shape having at least one peak in a torque region lower than an intermediate torque between the minimum torque and the maximum torque with respect to output characteristics or efficiency characteristics of the saw blade in a normal use torque range And a second setting mode for forming an approximately mountain-shaped second characteristic curve having at least one peak in a torque region exceeding the intermediate torque. Circular saw. The circular saw according to claim 1,
The transmission mechanism includes a first torque corresponding to a peak of the first characteristic curve in the first setting mode, and a second torque corresponding to a peak of the second characteristic curve in the second setting mode. The circular saw is characterized in that the ratio of the second torque to the first torque is 1.5 to 2.5. The circular saw according to claim 1,
The speed change mechanism includes a first power transmission path for transmitting torque of an input shaft driven by the power source to the output shaft of the saw blade in the first setting mode, and the input in the second setting mode. A second power transmission path for transmitting the torque of the shaft to the output shaft;
The first power transmission path includes a first drive gear connected to the input shaft, and a first driven gear engaged with and engaged with the first drive gear and connected to the output shaft,
The second power transmission path includes a second drive gear connected to the input shaft, and a second driven gear engaged with and engaged with the second drive gear and connected to the output shaft,
The first gear ratio of the first driven gear to the first drive gear and the second gear ratio of the second driven gear to the second drive gear, and the second gear ratio to the first gear ratio. A circular saw having a gear ratio of 1.5 to 2.5. A circular saw according to any one of claims 1-3,
A detection mechanism for detecting torque acting on the saw blade,
The speed change mechanism switches from the first setting mode to the second setting mode when the detected torque exceeds the intermediate torque based on the detected torque detected by the detecting mechanism, while the detected torque A circular saw having a configuration that switches from the second setting mode to the first setting mode when the torque falls below the intermediate torque.

Images