JP5652320B2 - Driving tool - Google Patents

Description

  The present invention relates to a driving tool for driving fasteners such as nails, staples and pins into objects such as wood, gypsum board, steel plate and concrete.

  There are electric driving tools for driving fasteners into objects. This electric driving tool includes a plunger urged in the fastener driving direction by a compression spring, and a driver for driving the fastener supplied from the magazine is fixed to the plunger. As a driving mechanism for contracting the plunger against the urging force of the compression spring, for example, there is Patent Document 1 (Japanese Patent No. 2658724) of the present patent applicant.

  The driving mechanism of this patent document 1 has two rotating gears arranged in parallel along the moving direction (vertical direction) of the plunger so as to face the plunger. The two rotating gears mesh with each other, and one drive pin projects from the plunger toward the plunger. On the other hand, the plunger is formed with engaging protrusions in the vertical direction corresponding to each drive pin. The plunger at the bottom dead center position is first lifted against the urging force of the compression spring by engaging the driving pin of the lower rotating gear with the lower engaging projection and rotating the lower rotating gear. Next, the plunger is lifted against the urging force of the compression spring by engaging the driving pin of the upper rotating gear with the upper engaging protrusion and rotating the upper rotating gear. When the upper rotation gear further rotates and the engagement between the drive pin and the upper engagement protrusion is disengaged, the plunger moves downward by the urging force of the compression spring, and the leading fastener supplied from the magazine is driven by the driver. Then, one cycle is completed.

  In the drive mechanism as described above, the guide mechanism of the plunger that moves in the vertical direction is such that the guide pieces formed on both sides of the plunger are engaged with the guide recesses, and the guide pieces slide in the guide recesses. ing. In such a guide mechanism, since the guide piece and the guide recess are sliding friction, it is difficult to further reduce the frictional resistance and make the operation of the plunger more smooth.

  This type of problem also applies to, for example, a drive mechanism that rolls up a plunger that is urged by a compression spring in a launch direction with a winch against the urging force of the compression spring.

  The drive mechanism and the driver are provided at positions facing each other with the plunger interposed therebetween. In this case, the guide mechanism is provided at a position where the driver of the plunger and the drive mechanism are not provided, for example, on both sides substantially orthogonal to a line connecting the drive mechanism and the driver. When the plunger is lifted against the elastic force of the compression spring by the drive mechanism, a force for tilting from the drive mechanism side to the driver side is applied. Along with this, the guide piece of the guide mechanism is also pressed against the inner surface of the guide recess, and the frictional resistance increases. For this reason, it is difficult to reduce the torque of the motor that is the drive source of the drive mechanism and further reduce the size and power consumption.

Japanese Patent No. 2658724

  The present invention has been made based on the above problems, and provides a driving tool that can reduce the frictional resistance of the guide mechanism of the plunger and realize further downsizing and power saving of the drive source. With the goal.

In order to solve the above-described problem, a driving tool according to the present invention is provided with a driver for driving a fastener, a plunger to which the driver is fixed and moving the fastener in a driving direction, and the plunger in the driving direction of the fastener. An urging member that urges, a drive mechanism that engages with the plunger at a position facing the driver across the plunger, and moves the plunger to the opposite side of the fastener firing direction; and a movement direction of the plunger And a guide mechanism of the plunger provided along the line. The guide mechanism, on opposite sides of a line substantially perpendicular connecting the said driver and the drive mechanism has a guide rail that is provided along the movement direction of the plunger.

  The plunger may be provided with two or more guide portions that can contact the guide rail in the moving direction.

  Further, the guide portion may be provided on both upper and lower sides with respect to the engaging portion between the plunger and the drive mechanism. Furthermore, a guide roller that is rotatable along the guide rail may be provided on the plunger.

  Furthermore, the driving tool may have a body, and a vibration isolating unit may be provided between the body and the guide mechanism.

  According to the present invention, the guide mechanism of the plunger is configured such that the guide roller is rotated on the guide rail, so that it becomes rolling friction instead of sliding friction, and the frictional resistance can be lowered. As a result, the drive source can be reduced in size and power can be saved, and the entire drive tool can be reduced in size and weight.

It is sectional drawing of the driving tool to which this invention was applied. It is a perspective view of the driving | operation mechanism of the fastener of the said driving tool. It is sectional drawing of the driving mechanism and buffer mechanism of the said driving tool. It is a perspective view of the driving mechanism of the driving tool. It is principal part sectional drawing which shows the guide groove of a driver. (A) is the perspective view which looked at the plunger from one side, (B) is the perspective view which looked from the other side. (A) is sectional drawing of the attachment structure of a driver and a plunger, (B) and (C) are sectional drawings of the reference example. (A)-(C) are the modifications of the attachment structure of the driver and plunger shown to FIG. 7 (A). It is a perspective view of a plunger and a guide mechanism. It is a longitudinal cross-sectional view of the driving mechanism of the driving tool. It is a cross-sectional view of the driving mechanism of the driving tool, and shows the II cross section of FIG. It is the modification which provided the vibration proof part in the guide mechanism of the plunger, (A) is a cross-sectional view, (B) is a side view. It is a figure which shows notionally the relationship between a 2nd fixing member, a pipe, a plunger, and a plunger spring, (A) shows the driving mechanism demonstrated as a form for implementing invention here, (B) Shows a modification of (A), and (C) shows a reference example. It is a perspective view of the drive mechanism of the driving tool. (A) is a plan view of the drive mechanism, and (B) is a cross-sectional view of the drive mechanism. It is a transition diagram of operation of a drive mechanism, and (A) shows the relation between the 1st and 2nd torque rollers and the 1st and 2nd engagement projections when a plunger is in a bottom dead center, ) Shows the relationship between the first and second torque rollers and the first and second engaging protrusions when the plunger is raised, and (C) shows the first relationship when the plunger reaches top dead center. The relationship between the first and second torque rollers and the first and second engaging protrusions is shown, and (D) shows the second torque roller and the second engaging protrusions when the plunger reaches top dead center. The state when the engagement of is released is shown. It is sectional drawing when a plunger exists in a bottom dead center. It is sectional drawing when a plunger raises to a top dead center. FIG. 10 is a cross-sectional view when the fastener is being lowered while the fastener is being driven. It is sectional drawing when a plunger reaches | attains bottom dead center. It is a side view which shows the state which the slider of the magazine was pulled out from the magazine main body and the accommodating part was exposed. It is sectional drawing of a magazine.

  Hereinafter, a driving tool to which the present invention is applied will be described in detail with reference to the drawings. Hereinafter, the driving tool will be described in the following order.

1. Overall configuration Body 3. Fastener driving mechanism 4. 4. Drive mechanism Buffer mechanism 6. Magazine 7. Overall operation and effects 8. Other variations

[1. overall structure]
As shown in FIG. 1, a driving tool 1 to which the present invention is applied is a tool for driving a fastener (nail, staple, pin, etc.) into an object such as wood, gypsum board, steel plate, concrete, etc. 10 and a magazine 50 for supplying fasteners to the body 10. In the body 10, a driving mechanism 20 for driving a fastener of the magazine 50 and a driving mechanism 32 for driving the driving mechanism 20 are provided. The body 10 is provided with a nose portion 11 having an injection port for punching fasteners at the front upper corner portion. The magazine 50 is provided in the nose portion 11 in a direction substantially perpendicular to the central axis direction of the body 10, that is, the fastener launching direction (arrow D1 direction).

[2. body]
As shown in FIG. 1, the body 10 has a body main body 10a, and a nose portion 11 having an injection port 11b for driving a fastener onto an object is provided on the front surface of the body main body 10a. As shown in FIGS. 1 and 2, the nose portion 11 is configured by combining a driver guide 11 c and a wear plate 11 d constituting the injection port 11 b. A contact arm 11a (see FIG. 2), which is a part of the safety device, is provided at the tip of the driver guide 11c, that is, the tip of the injection port 11b. The contact arm 11a normally protrudes around the injection port 11b, and permits operation of the trigger in conjunction with the trigger device when pressed against the object. In this nose portion 11, a magazine 50 is attached to a wear plate 11d.

  Further, the body main body 10a is provided with a grip portion 12 to be gripped by the user and an auxiliary grip portion 13 to assist the grip portion 12 so as to be substantially orthogonal to the central axis, that is, to be substantially parallel to the magazine 50. It has been. The grip portion 12 and the auxiliary grip portion 13 are connected to each other at a lower end portion by a bridging portion 14 and have a substantially annular shape so that the grip portion 12 can be gripped. The bridging section 14 is an electric circuit section that incorporates a microcomputer that controls the overall operation in response to input from various detection switches such as a power supply circuit, a drive motor control circuit, and a detection switch of the contact arm 11a. A substrate 17 is provided. This microcomputer drives an LED when an LED that is turned on during operation or an LED for illumination is provided on one side of the magazine or the like.

  Here, the position where the printed wiring board 17 is provided is provided in the bridging portion 14, but is not particularly limited as long as it is an empty space portion of the body 10. That is, the printed wiring board 17 may be provided in an empty space part in the body main body 10 a, the grip part 12, or the auxiliary grip part 13. The printed wiring board 17 may be divided and provided at a plurality of locations.

  Moreover, the trigger 15 is provided in the base part with the body main body 10a of the grip part 12 in the back side of the body main body 10a so that it may protrude in the annular part side. Further, the bridging portion 14 is provided with a battery mounting portion to which the battery pack 16 is mounted on the lower surface side. The battery pack 16 to be attached to the battery attachment portion incorporates a secondary battery such as a lithium ion secondary battery or a nickel hydride secondary battery, and a drive mechanism in the body 10 via the printed wiring board 17. Supply power to etc.

  In addition, the grip part 12 and the auxiliary | assistant grip part 13 are not substantially perpendicular | vertical with respect to the axial direction of the body 10, and may be provided so that it may curve forward or back, or may incline.

  A description will be given of the arrangement of parts in the body 10 as described above. A driving mechanism 20 for driving a fastener is disposed in the body main body 10a, and the driving mechanism 20 is driven in the auxiliary grip portion 13. A drive mechanism 32 is provided. Next, the fastener driving mechanism 20 will be described.

[3. Fastener driving mechanism]
As shown in FIG. 1 to FIG. 4, the fastener driving mechanism 20 disposed in the body main body 10 a includes a first fixing member 21 and a second fixing member 22 that are positioned at both ends. The first fixing member 21 and the second fixing member 22 are connected in a state of being separated by the guide rails 23 and 23. Further, a pipe 24 is disposed between the first fixing member 21 and the second fixing member 22, and a plunger 25 and a biasing member that biases the plunger 25 in one direction are provided on the pipe 24. A plunger spring 26 is wound around. In addition, a driver 27 for driving a leading fastener supplied from the magazine 50 is fixed to the plunger 25. The driver 27 drives the leading fastener supplied from the magazine 50 into the injection port 11 b, is guided by the guide groove 27 c of the driver guide 11 c, and moves linearly in accordance with the operation of the plunger 25.

  Specifically, as shown in FIG. 5, the driver 27 is guided so as to be sandwiched between a driver guide 11 c and a wear plate 11 d constituting the nose portion 11. That is, a guide portion 27b that engages with a guided portion 27a formed on the surface of the driver 27 is formed on the inner surface of the driver guide 11c that faces the wear plate 11d. The guided portion 27a and the guide portion 27b guide the linear movement of the driver 27 by engaging the concaves and convexes formed corresponding to each other. Further, the wear plate 11d is formed with a guide groove 27c that engages with the driver 27 on a surface facing the driver guide 11c. When the driver guide 11c and the wear plate 11d are coupled, the driver 27 is moved linearly by engaging the guided portion 27a with the guide portion 27b and engaging the driver 27 with the guide groove 27c. become.

  As shown in FIGS. 2 to 4, the first fixing member 21 and the second fixing member 22 are fixed to both ends of linear guide rails 23, 23 for guiding the movement of the plunger 25 by screwing or the like. In this way, they are kept separated from each other. Further, as shown in FIG. 3, the first and second fixing members 21 and 22 have a concave first support portion 21a and a convex second support portion 22a that support the pipe 24 on opposite surfaces. And are provided. The pipe 24 is fixed between the first fixing member 21 and the second fixing member 22 by fitting both ends to the first support portion 21a and the second support portion 22a.

  As shown in FIGS. 1, 2 and 6, a plunger 25 is attached to the pipe 24. As shown in FIGS. 6A and 6B, the plunger 25 has an insertion portion 25a through which the pipe 24 is inserted, and a fixed piece 28 to which the driver 27 is fixed. A base end portion of the long thin plate driver 27 is fixed to the fixing piece 28 by screwing or the like.

  Specifically, as shown in FIG. 7A, the fixed piece 28 is provided with a mounting protrusion 28a on the mounting surface of the driver 27, the top surface of which is flat and higher than the surroundings, and a screw hole 28b. ing.

  The driver 27 is formed with an insertion hole 28c at the base end. The insertion hole 28 c is fitted into the mounting protrusion 28 a of the fixed piece 28. Here, the height of the mounting protrusion 28 a is formed to be larger than the thickness of the base end portion of the driver 27. In the driver 27, when the insertion hole 28c is fitted into the mounting protrusion 28a, a bolt 28d is tightened in the screw hole 28b. Then, the head portion 28e of the bolt 28d is not directly pressed against the base end portion of the driver 27, but is pressed against the top surface of the mounting projection 28a. Therefore, the driver 27 is attached in a state of being rotatable around the attachment protrusion 28a, that is, like swinging. As a result, even when the plunger 25 sliding with respect to the pipe 24 is lifted by the drive mechanism 43 against the elastic force of the plunger spring 26, even if the plunger 25 may be tilted by the driving mechanism 43, it is guided. Since the driver 27 guided by the portion 27a, the guide portion 27b, and the guide groove 27c rotates around the mounting protrusion 28a, the sliding resistance of the driver 27, the guided portion 27a, the guide portion 27b, and the guide groove 27c Can be prevented from becoming large. That is, the energy efficiency when driving the driver 27 can be improved.

  When the driver 27 is attached to the plunger 25 in a swinging manner, as shown in FIG. 7B, a bolt 28d is used instead of a bolt 28d, and a screw hole 28b is formed through a through hole. 28h, the pin 28g can be held by the sheet metal 28g, and the pin 28f can be prevented from falling off. At this time, the fixed piece 28 is flat without providing the mounting protrusion 28a. In FIG. 7A, the use of the bolt 28d eliminates the need for the sheet metal 28g, thereby reducing the number of parts and realizing miniaturization.

  When the driver 27 is attached to the plunger 25 in a swinging manner, as shown in FIG. 7C, the insertion hole 28c is fitted into the attachment projection 28a and pressed by the sheet metal 28g. It is also possible to prevent the drop from the mounting protrusion 28a. In FIG. 7A, the use of the bolt 28d eliminates the need for the sheet metal 28g, so that the number of parts can be reduced accordingly.

  FIG. 8A is a modification of FIG. 7A. In FIG. 8A, a washer 28i is provided inside the insertion hole 28c of the driver 27 in place of the mounting protrusion 28a, and the head 28e of the bolt 28d fastened to the screw hole 28b is pressed against the washer 28i. It has become. Also in the example of FIG. 8A, since the bolt 28d is used and the sheet metal 28g is not required, the number of parts can be reduced correspondingly, and downsizing can be realized. Further, the fixed piece 28 is reduced in size because the mounting protrusion 28a is not provided.

  In FIG. 8B, the screw hole 28b is a through hole 28h, a screw portion 28j is provided only at the tip of the bolt 28d, and the bolt 28d is tightened with a nut 28k from the back surface of the fixed piece 28. In the example of FIG. 8B as well, the bolt 28d is used and the sheet metal 28g is unnecessary, so that the number of parts can be reduced and the size can be reduced. Further, the fixed piece 28 is reduced in size because the mounting protrusion 28a is not provided.

  In FIG. 8C, a screw protrusion 28m is provided on the fixed piece 28, a washer 28i is provided on the inner side of the insertion hole 28c of the driver 27, and a nut 28k is fastened to the screw protrusion 28m. Also in the example of FIG. 8C, the bolt 28d is used and the sheet metal 28g is not required, and accordingly, the number of parts can be reduced and the miniaturization can be realized.

  Further, the first torque roller 41 of the drive mechanism 32 that moves the plunger 25 is engaged with the opposite side of the fixed piece 28 of the plunger 25 as shown in FIGS. 6 (A) and 6 (B). A first engagement protrusion 29 and a second engagement protrusion 30 with which the second torque roller 42 is engaged are provided.

  Furthermore, as shown in FIGS. 6A and 6B and FIGS. 9 to 11, the plunger 25 is provided with a fixed piece 28 and first and second engaging protrusions 29 and 30. Guide rollers 31a and 31b serving as a guide mechanism for the plunger 25 are provided on both sides, which are not present, that is, on both sides substantially orthogonal to the straight line connecting the fixed piece 28 and the first and second engaging protrusions 29 and 30. Two are provided.

  Specifically, the support piece 25b, 25b is provided in the plunger 25 so as to slide along the pipe 24 inserted through the insertion portion 25a and move along the pipe 24. Each of the support pieces 25b, 25b is provided with a plunger spring 26 on the inner side, and on the outer side, guide rollers 31a, 31b are provided side by side in the movement direction of the plunger 25. As shown in FIG. 10, the guide rollers 31a and 31b are attached to the support pieces 25b and 25b by fixing the shafts 25d and 25d to the shaft holes 25c and 25c provided in the support pieces 25b and 25b, for example. .

  The guide rollers 31a and 31b rotate by engaging with the concave guide grooves 23a and 23a of the guide rails 23 and 23 fixed to the first and second fixing members 21 and 22, respectively. The guide rails 23 and 23 are provided so as to cover the shafts 25d and 25d of the guide rollers 31a and 31b so as not to drop off in the directions of the shafts 25d and 25d. As described above, the guide rails 23, 23 have the first and second fixing members 21, 22 attached to the pipe 24, and the first and second fixing members 21, 22 further have fixing members 23 b such as screws. Fixed by. By the way, the driver 27 and the drive mechanism 32 to be described next are provided at positions facing each other with the plunger 25 interposed therebetween (see FIG. 17), and the guide rails 23 and 23 are positions where the driver 27 and the drive mechanism 32 are not provided. That is, it is provided on both sides substantially orthogonal to the line connecting the driver 27 and the drive mechanism 32 (see FIG. 10). In operation, when the plunger 25 is lifted against the elastic force of the plunger spring 26 by the drive mechanism 32, a force in the direction of the arrow D6 in FIG. 3 tilts from the drive mechanism 32 side to the driver 27 side is applied. However, the plunger 25 becomes rolling friction by engaging and rotating the guide rollers 31a and 31a with the guide rails 23 and 23, and the friction resistance can be lowered. Thereby, the plunger 25 can move smoothly between the first fixing member 21 and the second fixing member 22.

  Note that a lubricant may be further applied to the guide grooves of the guide rails 23 and 23. Further, the number of guide rollers 31a and 31a provided on each side is not limited to two, and may be one or three or more.

  By the way, since the guide rollers 31a and 31b slide in the guide rails 23 and 23, they cause operation noise and vibration during sliding. Therefore, as shown in FIGS. 12A and 12B, when the driving mechanism 20 is disposed on the body main body 10a, the guide rails 23 and 23 and the first arrangement of the body main body 10a are arranged. The first and second anti-vibration components that serve as anti-vibration units are provided between the second fixing member 22 to which the guide rails 23 and 23 are fixed and the second arrangement portion 10c of the body main body 10a. The members 23c and 23d may be interposed. The first and second vibration isolation members 23c and 23d are vibration absorbing materials such as rubber, for example. Specifically, as shown in FIGS. 12 (A) and 12 (B), the outer surfaces of the guide rails 23 and 23 are portions that come into contact with the first arrangement portion 10b of the body main body 10a. For example, the first vibration isolation member 23c, which is a rubber sheet, is attached. The first vibration isolation member 23c may be attached to a plurality of portions instead of being attached to substantially the entire outer surface of the guide rails 23, 23.

  Further, as shown in FIG. 12B, the outer surface of the second fixing member 22 is also a portion that comes into contact with the second arrangement portion 10c of the body main body 10a, and also serves as a receiving surface for vibration during driving. Therefore, a second vibration isolation member 23d, which is a rubber sheet, for example, is also provided between the second fixing member 22 and the second arrangement portion 10c of the body main body 10a. Note that the second vibration isolation member 23d may be provided between the first fixing member 21 and the arrangement portion of the body main body 10a.

  In the example of FIGS. 12A and 12B, the vibrations generated by the sliding of the guide rollers 31a and 31a in the guide rails 23 and 23 at the time of driving are the first and second vibrations. Since it can be absorbed by the vibration isolating members 23c and 23d, the operation sound can be reduced.

  As shown in FIGS. 2, 3, and 10, the plunger spring 26 is a compression coil spring, and is inserted in the region between the second fixing member 22 and the plunger 25 through which the pipe 24 is inserted. The plunger spring 26 urges the plunger 25 abutted against the other end in the direction of the arrow D1 in FIGS. 2 and 3 when the fastener is driven by being abutted against the second fixing member 22. When the plunger spring 26 is inserted into the pipe 24, the plunger spring 26 can be prevented from bending in a direction different from the central axis during expansion and contraction, and the elastic energy loss can be reduced.

  13 conceptually describes the relationship between the pipe 24, the plunger 25, and the plunger spring 26, the driving mechanism 20 described above has the plunger 25 and the pipe 25 as shown in FIG. The plunger spring 26 is inserted, and the plunger spring 26 is compressed and extended between the plunger 25 and the second fixing member 22 so that the plunger 25 moves along the pipe 24. Thereby, since the plunger spring 26 is guided by the pipe 24, it is prevented that the plunger spring 26 bends in a direction different from the central axis even during expansion and contraction. Similar effects can be realized with the configuration shown in FIG. Specifically, in the example of FIG. 13B, the plunger 25 is not inserted into the pipe 24, but the pipe 24 is fixed to the plunger 25 and inserted into the insertion hole 22b of the second fixing member 22, and the plunger spring. 26 is wound around the pipe 24 and disposed between the plunger 25 and the second fixing member 22. In the plunger 25, when the plunger spring 26 contracts and rises, the pipe 24 projects from the insertion hole 22 b of the second fixing member 22. In the example of FIG. 13B as well, the plunger spring 26 is guided by the pipe 24, so that it is prevented from being bent in a direction different from the central axis during expansion and contraction.

  In contrast, in the example of FIG. 13C, the plunger spring 26 is disposed between the plunger 25 and the second fixing member 22 without using the pipe 24. The second fixing member 22 is provided with a guide protrusion 22 c that guides the expansion and contraction of the plunger spring 26. In the example of FIG. 13C, it is necessary to provide a gap 22 d longer than the movement distance of the plunger 25 between the top surface of the guide protrusion 22 c of the second fixing member 22 and the plunger 25. In the example of FIGS. 13A and 13B where the guide protrusion 22c does not exist, the gap 22d is guided by the pipe 24 over the entire length of the plunger spring 26 as compared with FIG. 13C. Therefore, it is possible to reliably prevent bending in a direction different from the central axis during expansion and contraction.

[4. Drive mechanism]
The drive mechanism 32 that drives the driving mechanism 20 configured as described above moves the plunger 25 from the first fixed member 21 side to the second fixed member 22 side against the elastic force of the plunger spring 26. . As shown in FIGS. 14, 15A and 15B, the drive mechanism 32 includes a drive motor 33 serving as a drive source. A worm 34 is attached to the spindle of the drive motor 33, and the worm 34 is engaged with a planetary gear mechanism 35 that serves as a speed reduction mechanism and is excellent in torque transmission. Furthermore, an arm gear 36 is engaged with the planetary gear mechanism 35. Further, the arm gear 36 is engaged with a first torque gear 37 that moves the plunger 25 against the elastic force of the plunger spring 26, and the first torque gear 37 is engaged with a second torque gear 38. Yes. The arm gear 36, the first torque gear 37, and the second torque gear 38 are supported by a single gear plate 39. That is, the gear plate 39 includes the arm gear 36 in addition to the shaft-shaped first support portion 39 a that supports the first torque gear 37 and the shaft-shaped second support portion 39 b that supports the second torque gear 38. A cylindrical third support portion 39c that pivotally supports the shaft. The arm gear 36, the first torque gear 37, and the second torque gear 38 are attached to a single gear plate 39, thereby suppressing variations in distance between the centers of the gears and improving the durability of the gear teeth. Furthermore, driving loss can be reduced.

  The first torque gear 37 is provided with a first torque roller 41 serving as a first drive protrusion that engages with the first engagement protrusion 29 of the plunger 25, and the second torque gear 38 includes a plunger 25. A second torque roller 42 serving as a second drive protrusion that engages with the second engagement protrusion 30 is provided. The first torque gear 37 and the second torque gear 38 meshing with each other rotate the first torque gear 37 in the direction of arrow R1 in FIG. 16, and the second torque gear 38 rotates in the direction of arrow R2 in FIG. Thereby, the 1st and 2nd torque rollers 41 and 42 follow the locus shown in Drawing 16 (A)-(D).

  As shown in FIG. 16 (A), the first engagement protrusion 29 of the plunger 25 moves when the plunger 25 is at the bottom dead center position when the first torque roller 41 of the first torque gear 37 moves. Above, when the first torque roller 41 starts moving in the circumferential direction from the lowest initial position and starts to rise, the first torque roller 41 is in a position to engage with the first torque roller 41. Further, as shown in FIG. 16B, the second engagement protrusion 30 is located immediately before the plunger 25 moves upward and the first torque roller 41 of the first torque gear 37 reaches the top. Further, the second torque roller 42 of the second torque gear 38 is disposed at a position where the second torque roller 42 starts to rise from the lowermost part. As described above, the first and second engagement protrusions 29 and 30 are provided with the first and second torque rollers 41 and 42 as the first and second torque gears 37 and 38 mesh with each other. The plungers 25 are sequentially engaged, and the plunger 25 is lifted from the first fixing member 21 side to the second fixing member 22 side against the elastic force of the plunger spring 26.

  In such a drive mechanism 32, when the drive motor 33 is started, the first torque gear 37 and the second torque gear 38 are opposite to each other (arrows R1, R2 in FIG. 16) via the planetary gear mechanism 35 and the arm gear 36. Direction). When the plunger 25 is at the bottom dead center position, as shown in FIG. 16A, the first torque roller 41 of the rotating first torque gear 37 is the bottom surface of the first engagement protrusion 29 of the plunger 25. Engage with. As the first torque gear 37 continues to rotate in the direction of the arrow R <b> 1, the first torque roller 41 rises and the plunger 25 is lifted against the plunger spring 26. Then, as shown in FIG. 16B, immediately before the first torque roller 41 reaches the top, the second torque roller 42 of the second torque gear 38 starts to rise in the direction of the arrow R2 from the bottom. The plunger 25 engages with the lower surface of the second engagement protrusion 30 of the plunger 25. Then, as the second torque gear 38 continues to rotate in the direction of the arrow R2, the plunger 25 is further lifted to the position shown in FIG. As shown in FIG. 16D, when the second torque gear 38 is further rotated and the second torque roller 42 is disengaged from the second engaging protrusion 30, the plunger 25 is moved by the elastic force of the plunger spring 26. The second fixing member 22 is driven in the direction of the first fixing member 21. At this time, the driver 27 coupled to the plunger 25 moves in the direction of the arrow D1 in FIGS. 1 to 3, drives the fastener supplied to the injection port 11b, drives it toward an external object, and drives the fastener. One cycle of work ends.

  Incidentally, the plunger 25 lifted by the first and second torque rollers 41 and 42 is lifted by the rotation of the first and second torque gears 37 and 38. Therefore, in addition to the force that lifts the plunger 25 in the direction opposite to the arrow D1 in FIG. 5 against the elastic force of the plunger spring 26, the first and second torque gears 37 and 38 are rotated in accordance with the rotation of the first and second torque gears 37 and 38. The second torque rollers 41, 42 move while slidingly contacting the first and second engaging protrusions 29, 30 so that the direction of the arrow D1 is parallel to the first and second engaging protrusions 29, 30. A force in a direction perpendicular to the direction is generated (in the direction of arrow X in FIG. 16). As a result, the plunger 25 that slides with respect to the pipe 24 rattles in the direction of the arrow X in FIG. 16 due to the minute gap between the pipe 24 and the insertion portion 25a.

  On the other hand, as shown in FIG. 5, the driver 27 attached to the plunger 25 is linear because the guided portion 27a is engaged with the guide portion 27b and the driver 27 is engaged with the guide groove 27c. Guided to move to. Here, as shown in FIG. 7 (A), the driver 27 is mounted in a state of being rotatable about the mounting projection 28a, that is, swinging. Accordingly, even when the plunger 25 sliding with respect to the pipe 24 is lifted by the drive mechanism 43 against the elastic force of the plunger spring 26, the driver 27 Since it rotates about the mounting protrusion 28a, the sliding resistance of the driver 27, the guided portion 27a, the guide portion 27b, and the guide groove 27c does not increase. Therefore, the energy efficiency when driving the driver 27 can be improved.

  In addition, although the number of torque gears demonstrated two examples here, it is determined according to the movement distance of the plunger 25, and is not limited to two especially, Even if it is one It may be three or more. According to the number of torque gears, that is, according to the number of torque rollers provided in the torque gear, the plunger 25 is provided with an engaging protrusion. The drive mechanism 32 that drives the driving mechanism 20 resists the elastic force of the plunger spring 26 by winding up the plunger 25 that is biased in the driving direction by the plunger spring 26 with a winch that pulls the plunger 25. It may be a drive mechanism that is moved.

[5. Buffer mechanism]
As shown in FIGS. 3, 10, and 17, the pipe 24 of the driving mechanism 20 is provided with a buffer mechanism 43 that buffers an impact when the fastener is driven. The buffer mechanism 43 includes a weight 44 disposed in the pipe 24, a weight spring 45 that urges the weight 44 in the direction of the second fixing member 22 (in the direction of arrow D2 in FIG. 17), and a second fixing member. 22, a weight stop 46 disposed inside the pipe 22, a wire 47 connecting the weight 44 inside the pipe 24 and the plunger 25 outside the pipe 24, and a pulley 48 that guides the wire 47. Yes.

  The weight 44 has a large-diameter portion 44 a and a small-diameter portion 44 b, and the large-diameter portion 44 a slides on the inner surface of the pipe 24 to move linearly inside the pipe 24. One end of the wire 47 is engaged with the protrusion 47a of the weight 44. The other end of the wire 47 is engaged with the protrusion 47 b of the plunger 25. The weight spring 45 is, for example, a compression coil spring disposed between the first fixing member 21 and the weight 44 in the pipe 24, and the weight 44 is moved in the direction of the second fixing member 22 (arrow D2 in FIG. 17). Direction). One end of the weight spring 45 is engaged with the large diameter portion 44 a of the weight 44.

  As shown in FIG. 17, when the plunger 25 is at the bottom dead center position, the weight 44 is abutted against the weight stop 46 on the second fixing member 22 side by the elastic force of the weight spring 45. Next, as shown in FIG. 18, when the plunger 25 is lifted up to the top dead center position by the drive mechanism 32, the weight 44 is pulled by the plunger 25 via the wire 47, so that the elastic force of the weight spring 45 is increased. Accordingly, the weight spring 45 is contracted and moved in the direction of the first fixing member 21 (counter arrow D2 direction (arrow D1 direction)).

  When the fastener is driven, the plunger 25 is vigorously moved in the direction of the first fixing member 21 (the direction of the arrow D1) by the elastic force of the plunger spring 26, as shown in FIGS. At this time, the driving tool 1 generates a reaction force P1 that is pushed up from the object. At this time, the wire 47 is temporarily slackened by the plunger 25 moving vigorously in the direction of the second fixing member 22 (arrow D1 direction) by the elastic force of the plunger spring 26, and the weight 44 is independent. The inside of the pipe 24 is moved in the direction of the second fixing member 22 (arrow D2 direction) by the elastic force of the plunger spring 26. This sets the weight of the plunger 25, the load of the plunger spring 26, the weight of the weight 44, and the load of the weight spring 45 so that the speed of the plunger 25 by the plunger spring 26 is faster than the speed of the weight 44 by the weight spring 45. This can be achieved. As a result, the driving tool 1 generates a pressing force that presses the weight 44 in the direction of the object by the reaction force P2 of the weight spring 45 that tries to push up the weight 44 in the direction of the second fixing member 22.

  Thus, in the buffer mechanism 43, the reaction force P1 pushed up from the object can be weakened or canceled by the reaction force P2 of the weight spring 45. In addition, the buffer mechanism 43 includes (the load P2 of the weight spring 45 + the load of the driving tool 1 (pressing load by the operator ± tool weight) P3) and (the reaction force P1 when the fastener is driven + the load of the plunger spring 26 (reaction) The force) P4) and the forces cancel each other, whereby the total reaction amount of the driving tool 1 can be determined. As described above, the driving tool 1 can appropriately set the load applied to the object when the fastener is driven. For example, when the fastener is driven into the interior finish, the pressing tool is pressed toward the target. It is possible to prevent the pressure from becoming too strong and scratching the surface.

[6. magazine]
As shown in FIGS. 1 and 2, the magazine 50 is attached to the nose portion 11 of the body main body 10a. Specifically, the magazine 50 is fixed to the wear plate 11d constituting the nose portion 11 by screwing or the like, and intersects the central axis direction of the body 10, that is, the direction in which the fastener is launched (arrow D1 direction), Then, it is provided linearly in a substantially orthogonal direction. When the magazine 50 is attached to the nose portion 11, the magazine 50 is attached to be separated from the auxiliary grip portion 13 of the body main body 10a. As shown in FIG. 21, the magazine 50 stores a plate-like connection band 51 in which individual fasteners are connected in a thin plate shape with an adhesive or the like (see FIG. 22). That is, the plate-like connecting band 51 has a substantially rectangular shape as a whole. As shown in FIG. 21, the magazine 50 includes a magazine main body 52 in which the plate-like connection band 51 is accommodated, and a slider 53 that slides in the direction of arrow D <b> 3 that is the extension direction of the magazine 50.

  The magazine main body 52 is provided with a storage portion 54 for storing the plate-like connecting band 51 in the longitudinal direction so as to approach the front side opposite to the auxiliary grip portion 13. The storage portion 54 is a recess having a depth approximately equal to the thickness of the plate-like connecting band 51. The bottom surface of the storage portion 54 is a support surface 54 a that supports a portion excluding one end portion where the tips of the fasteners of the plate-like connection band 51 are arranged.

  A guide portion 55 is provided on the side edge of the storage portion 54 in the driving direction of the fastener in order to guide one end portion in which the tip ends of the fasteners of the plate-like connecting band 51 are arranged in the longitudinal direction. Specifically, the guide portion 55 is provided by a substantially concave guide member 56 as shown in FIG. The guide member 56 connects the first and second guide pieces 56a and 56b, and the first and second guide pieces 56a and 56b in which a pair of opposing pieces guide one end of the plate-like connecting band 51, It is comprised from the positioning piece 56c which positions the one end part of the plate-shaped connection belt | band | zone 51 located in the back of a recessed part.

  As shown in FIG. 22, the side edge of the storage portion 54 in the direction in which the fastener is driven out is formed lower by the thickness of the first guide piece 56a on the support surface 54a side of the storage portion 54, and the first guide piece 56a is formed. When the is disposed, the support surface 54a and the surface of the first guide piece 56a are formed to have the same height. The positioning piece 56 c serves as a positioning wall for positioning one end portion of the plate-like connection band 51, and has a width slightly larger than the thickness of one end portion of the plate-like connection band 51. Further, the second guide piece 56 b that is separated from the support surface 54 a of the storage portion 54 is formed to have a length (for example, 2 to 8 mm) that covers one end of the plate-like connecting band 51. The inner surface of the second guide piece 56 b is a guide surface at one end of the plate-like connecting band 51.

  An extraction groove 57 is formed continuously between the support surface 54 a of the storage portion 54 and the first guide piece 56 a of the guide member 56. The take-out groove 57 is a recess provided in a straight line substantially parallel to the positioning piece 56c, so that at least the end portion 57a on the auxiliary grip portion 13 side of the body main body 10a does not overlap the tip of the second guide piece 56b. Is formed. Here, the extraction groove 57 is further provided so as to be continuous from the tip of the second guide piece 56b in a plan view, that is, not to overlap the second guide piece 56b. In the take-out groove 57, the end 57a of the body main body 10a on the side of the auxiliary grip 13 is an inclined surface so that the plate-like connecting band 51 can be raised obliquely.

  In such a magazine 50, the slider 53 is slid in the direction of the arrow D <b> 3, which is the front end side of the magazine 50, so that the storage portion 54 is exposed to the outside and the plate-like connecting band 51 can be taken in and out. As shown in FIGS. 21 and 22, the plate-like connection band 51 is formed in the direction of the arrow D4 from the auxiliary grip portion 13 side of the body main body 10a, with one end portion where the tips of the fasteners of the plate-like connection band 51 are arranged as the insertion end. It is inserted into the guide part 55. Then, the plate-like connecting band 51 is inserted between the first and second guide pieces 56a and 56b so as to be along the support surface 54a of the storage portion 54, that is, to lie on the support surface 54a. 56c. Thereafter, the magazine 50 is slid in the direction of the opposite arrow D3 on the base side, whereby the storage portion 54 is closed and the driving tool 1 can be used.

  On the other hand, when the plate-like connection band 51 stored in the storage portion 54 is taken out, as shown in FIG. 22, first, the plate-like connection band 51 is located on the side of the auxiliary grip portion 13 of the body body 10a in FIG. Slide in the direction of the opposite arrow D4. The plate-like connecting band 51 is pressed into the take-out groove 57 by the user's finger or the like when one end of the plate-like connecting band 51 where the tips of the fasteners line up approaches the take-out groove 57. Then, the plate-like connecting band 51 rises along the inclined surface of the end 57a on the auxiliary grip portion 13 side of the take-out groove 57, and can be easily taken out by being gripped by the user.

  As shown in FIGS. 21 and 22, the magazine 50 of the driving tool 1 is provided with an extraction groove 57. Therefore, the plate-like connecting band 51 is slid toward the auxiliary grip portion 13 of the body main body 10a to be extracted. By pressing the groove 57, the plate-like connecting band 51 can be easily taken out. In the driving tool 1, the gap 58 between the magazine 50 and the auxiliary grip portion 13 can be reduced, and the overall size can be reduced.

  The shape of the magazine 50 may be provided so as to be bent forward or backward rather than substantially perpendicular to the axial direction of the body 10.

[7. Overall operation and effects]
Operation | movement of the driving tool 1 comprised as mentioned above is demonstrated. First, when the fastener is driven into an object such as wood, gypsum board, steel plate, or concrete, the contact arm 11a of the nose portion 11 is pressed against the object as shown in FIG. Next, the trigger 15 is pulled, and when this is detected by a microswitch or the like, the drive motor 33 of the drive mechanism 32 is driven.

  Then, as shown in FIG. 16A, the first torque roller 41 of the rotating first torque gear 37 is engaged with the lower surface of the first engagement protrusion 29 of the plunger 25, and the plunger 25 is moved to the plunger. It is lifted against the spring 26 in the direction of the opposite arrow D1. Then, as shown in FIG. 16B, the second torque roller 42 of the second torque gear 38 immediately before the first torque roller 41 reaches the uppermost portion, the second engagement protrusion of the plunger 25. The plunger 25 is engaged with the lower surface of the portion 30, and the plunger 25 is lifted in the direction opposite to the arrow D1 against the plunger spring 26 and moved to the position shown in FIG. Next, as shown in FIG. 16D, when the second torque gear 38 further rotates and the second torque roller 42 is disengaged from the second engagement protrusion 30, the plunger 25 becomes elastic force of the plunger spring 26. As a result, the second fixing member 22 moves vigorously in the direction of the first fixing member 21. At this time, the driver 27 coupled to the plunger 25 moves in the direction of the arrow D1 in FIGS. 2 and 6, drives the fastener supplied to the injection port 11b, drives it toward an external object, and drives the fastener. One cycle of work ends.

  Thus, when the fastener is driven, the plunger 25 moves vigorously in the direction of the first fixing member 21 (the direction of the arrow D1) by the elastic force of the plunger spring 26, as shown in FIGS. At this time, the driving tool 1 generates a reaction force P1 that is pushed up from the object. At this time, the wire 47 is temporarily slackened by the plunger 25 moving vigorously in the direction of the second fixing member 22 (arrow D1 direction) by the elastic force of the plunger spring 26, and the weight 44 is independent. The inside of the pipe 24 is moved in the direction of the second fixing member 22 (arrow D2 direction) by the elastic force of the plunger spring 26. As a result, the driving tool 1 generates a pressing force that presses the weight 44 in the direction of the object by the reaction force P2 of the weight spring 45 that tries to push up the weight 44 in the direction of the second fixing member 22. Thereby, the driving tool 1 can weaken or cancel the reaction force P1 pushed up from the object by the reaction force P2 of the weight spring 45.

  In the fastener driving operation of the driving tool 1 as described above, the plunger 25 is moved linearly as the guide rollers 31a and 31a are guided by the guide rails 23 and 23 as shown in FIGS. The By the way, the driver 27 and the drive mechanism 32 including the first and second torque gears 37 and 38 are provided at positions facing each other across the plunger 25, and the guide rails 23 and 23 are connected to the driver 27 and the drive mechanism 32. Are provided on both sides substantially perpendicular to the line connecting the two. In operation, when the plunger 25 is lifted against the elastic force of the plunger spring 26 by the drive mechanism 32, a force in the direction of the arrow D6 in FIG. 3 tilts from the drive mechanism 32 side to the driver 27 side is applied. However, since the guide rollers 31a and 31a are engaged with the guide rails 23 and 23 and rotated, the plunger 25 becomes rolling friction and the frictional resistance is reduced. Thereby, the plunger 25 can move smoothly between the first fixing member 21 and the second fixing member 22. Therefore, the energy efficiency when driving the driver 27 can be improved.

[8. Other variations]
The driving tool 1 to which the present invention has been applied has been described above. However, the present invention also includes a compressed air type, a combustion gas type, a driving mechanism driven by compressed air, a combustion gas, a solenoid, etc. You may apply to drive tools, such as a solenoid type.

DESCRIPTION OF SYMBOLS 1 Driving tool, 10 body, 10a body main body, 10b 1st arrangement | positioning part, 10c 2nd arrangement | positioning part, 11 nose part, 11a contact arm, 11b injection port, 11c driver guide, 11d Wear plate, 12 grip Part, 13 auxiliary grip part, 14 bridging part, 15 trigger, 16 battery pack, 17 printed wiring board, 20 driving mechanism, 21 first fixing member, 21a first support part, 22 second fixing member, 22a 2nd support part, 22b insertion hole, 22c guide protrusion, 22d clearance, 23 guide rail, 23a guide groove, 23b fixing member, 23c, 23d vibration isolation member, 24 pipe, 25 plunger, 25a insertion part, 25b support piece , 25c shaft hole, 25d shaft, 26 plunger spring, 27 driver, 27a Part, 27b guide part, 27c guide groove, 28 fixing piece, 28a mounting protrusion, 28b screw hole, 28c insertion hole, 28d bolt, 28e head, 28f pin, 28g sheet metal, 28h through hole, 28i washer, 28j screw part , 28k nut, 28m screw projection, 29 first engagement projection, 30 second engagement projection, 31a, 31b guide roller, 32 drive mechanism, 33 drive motor, 34 worm, 35 planetary gear mechanism, 36 arm gear 37 First torque gear, 38 Second torque gear, 39 Gear plate, 39a-39c Support portion, 41 First torque roller, 42 Second torque roller, 43 Buffer mechanism, 44 Weight, 44a Large diameter portion, 44b Small diameter part, 45 weight spring, 46 weight stop, 47 wire, 47a, 47b protrusion, 48 pulley, 50 magazine, 51 plate-like connecting band, 52 magazine body, 53 slider, 54 storage portion, 54a support surface, 55 guide portion, 56 guide member, 56a first guide piece, 56b second guide piece, 56c Positioning wall, 57 extraction groove, 57a end, 58 gap, 59 side wall, 59a guide piece

Claims (5)

With a driver driving fasteners,
A plunger to which the driver is fixed and the fastener is moved in a launch direction;
An urging member that urges the plunger in the fastener driving direction;
A drive mechanism that engages the plunger at a position facing the driver across the plunger and moves the plunger to the opposite side of the fastener firing direction;
A plunger guide mechanism provided along the direction of movement of the plunger,
The guide mechanism is
On both sides of a line substantially perpendicular connecting the said driver and the drive mechanism has a guide rail that is provided along the direction of movement of the plunger
A driving tool characterized by that .   The plunger
  The guide part that can contact the guide rail
  There are two or more places in the direction of movement
  The driving tool according to claim 1.   The guide part
  For the engagement portion between the plunger and the drive mechanism,
  Provided on both upper and lower sides
  The driving tool according to claim 2.   A guide roller that can rotate along the guide rail.
  Provided on the plunger
  The driving tool according to claim 2. Has a body,
An anti-vibration unit is provided between the body and the guide mechanism.
The driving tool according to any one of claims 1 to 4 , characterized in that:

Images