This application is the U.S. National Phase under 35 US.C. § 371 of International Application No. PCT/JP2019/017900, filed on Apr. 26, 2019, which claims the benefit of Japanese Application No. 2018-095939, filed on May 18, 2018, the entire contents of each are hereby incorporated by reference.
The present invention relates to a driving tool that strikes a fastener by using a driver blade.
Among driving tools each of which moves a driver blade and strikes a fastener by using the driver blade, pneumatic-type driving tools have been known, the pneumatic-type driving tool driving the driver blade for shot by further compressing air of a pressure chamber in a main body due to the movement of the driver blade and releasing the compressed air.
A configuration of the pneumatic-type driving tool as described above is disclosed in, for example, a Patent Document 1, and the Patent Document 1 discloses a driving tool in which a load on a convex portion of the driver blade is reduced.
Patent Document 1: Japanese Patent Application Laid-Open Publication No. 2018-34258
In the pneumatic-type driving tool, the compressed air filling the pressure chamber is sealed by a highly airtight sealing structure, and the pneumatic-type driving tool includes: a cylindrical cylinder at one end of the pressure chamber; and a driver blade capable of storing compressed energy by sliding inside this cylindrical cylinder in an axial direction. And, when the compressed energy is released, the fastener is driven (tucked) by the driver blade.
At the driving, a head of a nail that is loaded in an injection path at an end of the driver blade is driven into a wood piece or others while being pushed. At this time, in the driving tool, generally, there is a case of occurrence of nail jamming in which the nail is jammed in an injection port. The larger a driving energy is, the larger a necessary power for solving the nail jamming is, and therefore, a lot of time and effort for solving the nail jamming are needed so often. Further, in the pneumatic-type driving tool, the driver blade is urged by the internal compressed air even in the nail jamming, and therefore, the time and effort for solving the nail jamming tends to increase.
At the time of the nail jamming, the nail is jammed in a gap between a side wall of the driver blade and a side wall of a concave portion of a blade guide that guides the driver blade, and the driver blade does not move, either. Therefore, there is an issue of difficulty in solving the nail jamming.
A purpose of the present invention is to easily solve the nail jamming in the driving tool.
A driving tool of the present invention includes: a striking driver configured to drive a driver blade that strikes a fastener; a main body having the striking driver; a first blade guide fixed to the main body; and a second blade guide attached to the first blade guide and configured to form an injection path for the fastener together with the first blade guide. And, the driver blade is arranged so as to go through a space made of two opposite side walls of the injection path, a bottom wall and a top wall, and either one of the two side walls is separated from the injection path.
According to the present invention, the nail jamming in the driving tool can be easily solved.
Hereinafter, one example of embodiments of the present invention will be explained in detail with reference to the drawings. A driving tool 10 according to the present first embodiment shown in
A structure of the driving tool 10 is explained to have: a cylindrical cylinder housing 11; a handle 12 that is continuously formed to the cylinder housing 11; and a nose portion 13 fixed to the cylinder housing 11. Further, a cylinder 15, a holder 16 and a pressure accumulator 17 are formed inside the cylinder housing 11, and a piston 18 is arranged so as to be reciprocable inside the cylinder 15. The nose portion 13 is a component forming an injection path 40 that is a path in which the fastener that is driven in by a driver blade 21 goes.
The driving tool 10 further has: a pressure chamber (striking driver) 19 configured to drive the driver blade 21 that strikes the fastener; and a main body 14 with the pressure chamber 19 including the cylinder housing 11. In other words, in the main body 14 of the driving tool 10, the pressure chamber 19 is formed as the striking driver. A sealing member 20 is attached to an outer circumferential surface of the piston 18, and the sealing member 20 is in contact with an inner circumferential surface of the cylinder 15 to form a sealing surface. The sealing member 20 seals the pressure chamber 19. Gas in a compressed state is encapsulated in the pressure chamber 19. The gas encapsulated in the pressure chamber 19 is air, inert gas or others, and, for example, nitrogen gas or rare gas can be also encapsulated therein. In the present first embodiment, an example of the encapsulation of the air in the pressure chamber 19 will be explained.
The piston 18 is movable in a direction of a centerline A1 of the cylinder 15. The piston 18 receives a pressure of the pressure chamber 19 and is urged in the direction of the centerline A1. The driver blade 21 is formed in the piston 18. The driver blade 21 is formed as one body with the piston 18, and the driver blade 21 and the piston 18 configure the striker 22. Each of the driver blade 21 and the piston 18 is made of a metal.
As shown in
A mounting portion 39 is connected to the handle 12. A battery 27 is attachable to and detachable from the mounting portion 39. The battery 27 supplies electric power to the electric motor 23. The battery 27 is a direct-current power supply.
Note that a case of a nail 28 as the fastener will be explained in the present first embodiment.
As shown in
As shown in
The electric motor 23 has a stator 35 that does not rotate with respect to a housing for use in the motor and a rotor 36 that can rotate inside the housing for use in the motor. The electric motor 23 of the present first embodiment is a brushless motor. The rotor 36 is fixed to an output shaft 38, and the output shaft 38 is supported by two bearings 37. The output shaft 38 is rotatable around an axis line A2.
The power transmission mechanism 24 shown in
The pinion pin 33 is engageable with and releasable from the protrusion portion 21a of the driver blade 21. When the pinion pin 33 engages with the protrusion portion 21a and when the pin wheel 32 rotates counterclockwise in
Specifically, a state of the power transform mechanism 24 is switched between the engaging state of the pinion pin 33 of the pin wheel 32 with the protrusion portion 21a and the releasing state of the same from the protrusion portion 21a by the rotation of the pin wheel 32 due to the driving of the electric motor 23. For example, when the pin wheel 32 rotates counterclockwise and when the pinion pin 33 engages with the protrusion portion 21a of the driver blade 21, the rotative force of the pin wheel 32 is transmitted to the driver blade 21, and the driver blade 21 and the piston 18 shown in
On the other hand, when the pinion pin 33 releases from the protrusion portion 21a, the rotative force of the pin wheel 32 is not transmitted to the driver blade 21, and the driver blade 21 and the piston 18 move in a direction (“R” direction) going away from the pressure chamber 19 due to the pressure of the pressure chamber 19.
In other words, in the driving tool 10 of the present first embodiment, the movements of the driver blade 21 in the direction coming close to the pressure chamber 19 and the direction going away from the pressure chamber 19 are made by the engaging/releasing of the plurality of protrusion portions 21a formed in the driver blade 21 with/from the plurality of pinion pins 33 included in the rotatable pin wheel 32 formed in the main body 14. Further, the movements are made by the rotation of the pin wheel 32 due to the driving of the electric motor 23 formed in the main body 14.
As described above, in the driving tool 10, the pressure chamber 19 is formed as the striking driver in the main body 14 of the driving tool, and the air that is stored in the pressure chamber 19 is further compressed by the movement of the driver blade 21 toward the pressure chamber 19. When the pinion pins 33 are released from the protrusion portions 21a, the compressed air is also released, the driver blade 21 is driven for shot by the releasing of the compressed air, and the nail 28 is driven into a desirable part such as a wood piece.
Next, in the driving tool 10 of the present first embodiment, a structure of the blade guide forming the injection path 40 in which the driver blade 21 moves will be explained.
In the driving tool, the nail jamming in which the nail is jammed in the injection port generally occurs in some cases. The larger the driving energy is, the larger the necessary power for solving the nail jamming is, and therefore, a lot of time and effort for solving the nail jamming are needed so often. Further, in the pneumatic-type driving tool 10, the driver blade 21 is urged by the internal compressed air even in the nail jamming, and therefore, the time and effort for solving the nail jamming tends to increase. The nail jamming is a phenomenon in which a jammed nail 44 is stuck between the driver blade 21 and an inner wall of the injection path 40 as shown in
The driving tool 10 of the present first embodiment has a structure that easily releases the stuck jam nail 44 at the time of the occurrence of the nail jamming.
As shown in
The driver blade 21 is arranged so as to go through the space 46 surrounded by two opposite side walls 40a and 40b of the injection path 40, a top wall 40c and a bottom wall 40d.
As shown in
In the structure shown in
In more detailed explanation, the side wall 40a formed in the first blade guide 41 is a part of the concave portion 41a of the first blade guide 41, and the side wall 40b formed in the second blade guide 42 is the convex portion 42a that protrudes from the second blade guide 42. In this structure, the top wall 40c is also a part of the concave portion 41a of the first blade guide 41.
In the concave portion 41a of the first blade guide 41, a housing portion 41b that houses the side wall 40b (convex portion 42a) formed in the second blade guide 42 is formed.
In the manner, in the structure shown in
In other words, the nail jamming of the driving tool 10 can be easily solved.
The side wall 40b that is separated from the injection path 40 when the second blade guide 42 is detached from the first blade guide 41 does not always need to be formed as one body with the second blade guide 42, and may be formed as a body different from the second blade guide 42.
It is only required to arrange the top wall 40c and the bottom wall 40d so as to be at least separatable from each other, and the side wall 40b that separates from the injection path 40 is formed in the bottom wall 40d. The side wall 40a that does not separate from the injection path 40 may be formed as one body with the top wall 40c or may be formed as a body different therefrom.
In the case of the pneumatic-type driving tool, when the nail jamming occurs, the jam nail 44 is stuck between the driver blade 21 and the side wall of the blade guide under a high pressure, and therefore, the jam nail 44 cannot be easily taken out. However, in the driving tool 10 of the present first embodiment, the jam nail 44 can be easily taken out.
In a case of an air-type driving tool, the driver blade 21 can be easily moved by pulling out an air hose. On the other hand, in the case of the pneumatic-type driving tool that always contains the compressed air, it is difficult to move the driver blade 21 toward the pressure chamber 19, and it is not easy to solve the nail jamming. However, in the driving tool 10 of the present first embodiment, the nail jamming can be easily solved in spite of the pneumatic type, and therefore, it is obvious that the driving tool 10 is effective as the pneumatic-type driving tool 10.
In the present second embodiment, as shown in
Since the outer wall surface 40ba of the side wall 40b that separates from the injection path 40 is the tilted surface as described above, a horizontal-directional component force is generated by a tilt component of the wall surface 40ba when the second blade guide 42 is detached from the first blade guide 41 as shown in
Therefore, the second blade guide 42 can be more easily detached from the first blade guide 41.
In the present third embodiment, as similar to the second embodiment, as shown in
In the manner, as similar to the second embodiment, as shown in
Further, in the structure of the present third embodiment, a clearance 47 shown in
In the manner, a space is formed in a portion of the stuck jam nail when the bolts 45 are loosened, and the space between the wall surface 40ba and the side wall 41aa is enlarged at the beginning of the loosening of the bolts 45, and therefore, the second blade guide 42 can be more easily detached from the first blade guide 41.
Further, in the structure of the present third embodiment, the first blade guide 41 and the second blade guide 42 are attached so as to be parallel to the outer wall surface 40ba of the side wall 40b that separates from the injection path 40. For example, the first blade guide 41 and the second blade guide 42 are attached at an angle causing the blade guides to be parallel to an extension direction “S” of the magazine 29 shown in
Specifically, the second blade guide 42 is joined to the magazine 29 that houses the plurality of nails 28, and the first blade guide 41 and the second blade guide 42 are attached so as to be parallel to the extension direction “S” of the magazine 29.
In other words, in the structure of the present third embodiment, both the first blade guide 41 and the second blade guide 42 are attached by the two bolts 45 so as to be parallel to the outer wall surface 40ba of the side wall 40b. At this time, the two bolts 45 are also attached at the same angle as those of the two blade guides. Therefore, in one example, the first blade guide 41, the second blade guide 42 and the two bolts 45 are attached to the nose portion 13 so as to be parallel to the extension direction “S” of the magazine 29.
In the manner, a slide direction of the second blade guide 42 in the detachment tilts from a contact portion between the jam nail 44 and the inner wall surface 40bb of the side wall 40b so as to be a direction going away from the jam nail 44, and therefore, the second blade guide 42 is easy to slide. In other words, the second blade guide 42 is easily detached.
As a result, the second blade guide 42 can be more easily detached from the first blade guide 41.
In a structure of the present fourth embodiment, as shown in
In other words, in the structure of the present fourth embodiment, as shown in
The third blade guide 43 has an engaging portion 43a that engages with an engaging portion 41c that is formed in the first blade guide 41, the engaging portion 43a being near the side wall and the engaging portion 41c being near the first blade guide. In the manner, when the second blade guide 42 is attached to the first blade guide 41, the engaging portion 43a near the side wall and the engaging portion 41c near the first blade guide engage with each other to form the side wall 43b of the injection path 40. When the first blade guide 41 and the second blade guide 42 are separated from each other, the engaging between the engaging portion 43a near the side wall and the engaging portion 41c near the first blade guide is canceled.
As shown in
In the manner, as shown in
Therefore, when the bolts 45 are loosened, the third blade guide 43 can easily move in a direction going away from the jam nail 44.
In the structure of the present fourth embodiment, as similar to the third embodiment, as shown in
In other words, also in the present fourth embodiment, each of the first blade guide 41 and the second blade guide 42 is attached at the angle that makes each blade guide parallel to the magazine 29, and the two bolts 45 are also attached at the same angle as those of the two blade guides. Note that the first blade guide 41, the second blade guide 42 and the two bolts 45 are attached to the nose portion 13 so as to be parallel to the extension direction “S” of the magazine 29 in one example.
In the manner, as similar to the third embodiment, as shown in
As a result, the second blade guide 42 can be more easily detached from the first blade guide 41.
As described above, the jam nail 44 can be more easily taken out in the structure of the present fourth embodiment than the structures of the first to third embodiments, and the nail jamming can be more easily solved.
In the structure of the present fourth embodiment, the third blade guide 43 is formed as the body different from the first blade guide 41 and the second blade guide 42. Therefore, when the third blade guide 43 is made of a material having a hardness that is higher than those of materials of the first blade guide 41 and the second blade guide 42, wall damage due to wearing against the jam nail 44 can be suppressed. In the manner, quality of the driving tool 10 can be improved.
The present invention is not limited to the foregoing embodiments, and various modifications can be made within the scope of the present invention. For example, in the first to fourth embodiments, the explanation has been made for the case of the mechanism using the pin wheel as the reeling mechanism of the drier blade 21. However, as the reeling mechanism of the driver blade 21, a reeling mechanism using a wire may be applicable.
10 . . . driving tool, 11 . . . cylinder housing, 13 . . . nose portion, 14 . . . main body, 15 . . . cylinder, 18 . . . piston, 19 . . . pressure chamber (striking driver), 21 . . . driver blade, 23 . . . electric motor (motor), 28 . . . nail (fastener), 29 . . . magazine, 31 . . . pin wheel shaft, 32 . . . pin wheel (rotary plate), 33 . . . pinion pin (pin), 40 . . . injection path, 41 . . . first blade guide, 42 . . . second blade guide, 43 . . . third blade guide, 46 . . . space
Number | Date | Country | Kind |
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JP2018-095939 | May 2018 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2019/017900 | 4/26/2019 | WO |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2019/220929 | 11/21/2019 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
2801417 | Jenny | Aug 1957 | A |
2947003 | Ericsson | Aug 1960 | A |
2954561 | Starr | Oct 1960 | A |
5368213 | Massari, Jr. | Nov 1994 | A |
20090026244 | Huang | Jan 2009 | A1 |
20090072002 | Ishizawa | Mar 2009 | A1 |
Number | Date | Country |
---|---|---|
2003-071741 | Mar 2003 | JP |
2015-047652 | Mar 2015 | JP |
2018-034258 | Mar 2018 | JP |
WO-2016174994 | Nov 2016 | WO |
Entry |
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International Search Report issued in corresponding International Patent Application No. PCT/JP2019/017900, dated Jun. 25, 2019, with English translation. |
Number | Date | Country | |
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20210316433 A1 | Oct 2021 | US |