1. Field of the Invention
The invention relates to a driving machine, more particularly, to a driving machine including a rack and pinion mechanism.
2. Description of Related Art
In the conventional art, the following driving machine has been proposed. Said driving machine includes: a nose; a housing, having the nose; a plunger, disposed in the housing; a blade, connected to the plunger and capable of firing a fastener via the nose; a rack, disposed on the plunger; and an engaging section, for engaging with a rack to transmit a driving force (Patent Document 1).
Patent Document 1: Japanese Patent Publication No. 2007-237345
The conventional driving machine is well-known for the mechanism used in driving nail by transmitting a driving kinetic energy stored in a fly wheel to the rack via the engaging section (a pinion section). Because the driving kinetic energy stored in the fly wheel is used, when aforesaid structure is used in the driving machine capable of driving long nails, improvements are sill to be made on a time lag until the sufficient driving kinetic energy is generated and supplied for driving nail.
For solving this practical issue, the invention aims to provide a driving machine as follows. The driving machine can achieve reciprocating movements of a rack using a simple mechanism for a smooth the driving machine and can smoothly engage and disengage the rack by reducing the friction.
The invention provides a driving machine, which includes: a nose, extending in a prescribed direction; a housing, having the nose; a blade, having an engaging section, movably guided in the housing in the prescribed direction, and capable of driving a fastener via the nose; and a transmission mechanism, having an engaged section for engaging with the engaging section in order to transmit a driving force. The transmission mechanism has a roller mechanism for guiding the engaging section and engaged section to disengage from each other.
In the driving machine according to aforesaid structure, the friction generated during engagement and disengagement may be reduced so the driving force may be smoothly transmitted because the roller mechanism is used to engage the engaging section with the engaged section. In this way, wearing or damage on the engaged section and the engaging section may be prevented as a result. Further, light weight, miniaturization, or reduction in manufacturing costs may be achieved for the driving machine because the blade may be moved without using the fly wheel.
Preferably, the engaged section includes a pinion and the roller mechanism, and includes one end portion for starting an engagement with the engaging section and another end portion for disengaging the engagement via the roller mechanism.
In the driving machine according to aforesaid structure, the driving force may be smoothly transmitted because the engagement and the disengagement take place at the end portions.
Preferably, the roller mechanism is capable of moving relative to the pinion in a circumferential direction of the pinion.
In the driving machine according to aforesaid structure, the friction during the engagement with the engaging section may be prevented or reduced by a roller shifting of the roller mechanism so the engaged section and the engaging section can smoothly engage. The so-called “smoothly engage” refers to allowing a part of the engaging section to be processed into different members including certain manufacturing deviation, or allowing a pitch of the engaging section to include certain manufacturing deviation. Besides, light weight, miniaturization, or reduction in manufacturing costs may be achieved for the driving machine because aforesaid effect may be achieved using the rack and pinion mechanism which belongs to a relatively simple mechanism.
Preferably, the transmission mechanism further includes a driving shaft for transmitting the driving force to the engaged section, where the driving shaft is connected to the pinion.
In the driving machine according to aforesaid structure, by connecting the driving shaft to the pinion, the driving force may be transmitted to the engaged section via the pinion using a simple structure.
Preferably, the transmission mechanism further includes a restriction section. The pinion is in contact with the roller mechanism at the restriction section so a relative shifting of the roller mechanism relative to the pinion is restricted.
In the driving machine according to aforesaid structure, excessive deformation or shifting of the transmission mechanism may be prevented and excessive deformation or damage on an elastomer may also be prevented.
Preferably, the engaging section includes a rack and a guided section guided by the roller mechanism, and the engaging section and the guided section are formed in different pitches.
In the driving machine according to aforesaid structure, by being formed in different pitches, the engaging section can include a large cross section to increase a tolerable loading of the engaging section. As a result, wearing or damage on the engaging section may be prevented, and a loading applied to the blade may be increased to thereby increase a nailing force. Moreover, because the engaged section includes a roller, the engaged section and engaging section can still smoothly engage even though the engaging section has a different pitch. The so-called “smoothly engage” refers to allowing a part of the engaging section to be processed into different members including certain manufacturing deviation, or allowing a pitch of the engaging section to include certain manufacturing deviation. Besides, light weight, miniaturization, or reduction in manufacturing costs may be achieved for the driving machine because aforesaid effect may be achieved using the relatively simple mechanism.
Preferably, the roller mechanism includes a roller formed by an elastomer material.
In the engaging section according to aforesaid structure, the engaging section and the engaged section can smoothly engage because the roller is the elastomer and the roller deforms during the engagement.
Preferably, the roller mechanism is connected to the pinion through an elastic member.
In the engaging section according to aforesaid structure, the pitch of the engaged section is variable because the elastic member deforms during the engagement. Therefore, the engaging section and the engaged section can still smoothly engage even though the engaging section has a different pitch.
The invention further provides a driving machine, which includes: a nose, extending in a prescribed direction; a housing, having the nose; a blade, having an engaging section, movably guided in the housing in the prescribed direction, and capable of driving a fastener via the nose; and a transmission mechanism, transmitting a driving force to the blade, The transmission mechanism includes a pinion capable of engaging with the engaging section, and a cam connected to the pinion through an elastic member and capable of engaging with the engaging section.
In the driving machine according to aforesaid structure, the cam or the pinion can shift in the circumferential direction when the engaging section engages with the cam or the pinion because the cam and the pinion are connected through the elastic member. Therefore, the engaging section and the engaged section can smoothly engage because the friction during the engagement of the engaged section and the engaging section may be prevented or reduced even though the pitch of the engaging section includes the deviation or the engaging section has a different pitch. Besides, a high tolerable loading may be provided in order to transmit a greater driving force because the engaged section includes a member larger than teeth of the pinion (i.e., the cam). As a result, wearing or damage on the engaged section may be prevented, or the loading applied to the blade may be increased to thereby increase the nailing force.
Besides, light weight, miniaturization, or reduction in manufacturing costs may be achieved for the driving machine because aforesaid effect may be achieved using the relatively simple mechanism.
Preferably, the transmission mechanism further includes a restriction section. The pinion is in contact with the cam at the restriction section so a relative shifting of the cam relative to the pinion is restricted.
According to aforesaid structure, excessive deformation of the transmission mechanism may be prevented and excessive deformation or damage on the elastomer may also be prevented.
In addition, the invention further provides a driving machine, which includes: a nose, extending in a prescribed direction; a housing, having the nose; a blade, having an engaging section, movably guided in the housing in the prescribed direction, and capable of driving a fastener via the nose; and a transmission mechanism, transmitting a driving force to the blade, The engaging section includes a rack and a guided section. The rack and the guided section are formed in different pitches. The transmission mechanism includes an engaged section for engaging with the engaging section and the guided section and formed in different pitches, and a driving shaft connected to the engaging section through an elastic member and transmitting a driving force to the engaged section.
In the driving machine according to aforesaid structure, the engaged section can shift in the circumferential direction during the engagement with the engaging section because the engaged section is connected to the driving shaft through the elastic member. Therefore, the engaging section and the engaged section can smoothly engage because the friction during the engagement of the engaged section and the engaging section may be prevented or reduced even though the pitch of the engaging section includes the deviation or the engaging section has a different pitch. Besides, the engaging section and the engaged section can include the teeth with the large cross section due to the different pitches, so as to increase the tolerable loading of the engaging section. As a result, wearing or damage on the engaged section may be prevented, or the loading applied to the blade may be increased to thereby increase the nailing force.
Besides, light weight, miniaturization, or reduction in manufacturing costs may be achieved for the driving machine because aforesaid effect may be achieved using the relatively simple mechanism.
Preferably, the transmission mechanism includes a restriction section. The pinion is in contact with the cam at the restriction section so a relative shifting of the cam relative to the pinion is restricted.
In the driving machine according to aforesaid structure, excessive deformation of the elastomer may be prevented by restricting the shifting by the restriction section. Therefore, plastic deformation and damage on the elastomer may be prevented.
Preferably, the elastic member includes at least one of a metal spring, an elastomer or an elastic resin.
In the driving machine according to aforesaid structure, applications corresponding to the embodiments may be conducted because the elastic member can adopt use of various materials. In all of various embodiments, the engaging section and the engaged section can smoothly engage.
Further, preferably, the transmission mechanism is able to conduct a rotation and transmit the driving force to the engaging section through the rotation, and a backward rotation restriction mechanism allowing a forward rotation and restricting a backward rotation for the transmission mechanism is disposed in the housing.
According to aforesaid structure, the backward rotation of the transmission mechanism may be restricted by the backward rotation restriction mechanism. In this way, a finishing grade may be favorably maintained and a usability may be improved.
In addition, preferably, the backward rotation restriction mechanism includes a one-way clutch.
According to aforesaid structure, the structure for restricting the backward rotation of the transmission mechanism may be achieved by using the relatively simple mechanism.
According to the invention, the following driving machine may be provided. Said driving machine can achieve the reciprocating movements of the rack by the simple mechanism and can reduce the friction so the rack can smoothly engage and disengage.
The accompanying drawings are included to provide a further understanding of the invention, and are incorporated in and constitute a part of this specification. The drawings illustrate embodiments of the invention and, together with the description, serve to explain the principles of the invention.
In the followings, one example of the driving machine (i.e., a driving machine 1 of electric type) according to the first embodiment is described with reference to
As shown in
The body section 2A mainly accommodates the punching mechanism 3 and has the bottom connected to the nose 4. Further, the body section 2A includes a cylinder 20 extending along the top/bottom direction, a piston 21, a piston bumper 23 and a pressure chamber 2a.
The driving section 7 mainly includes a motor 71, an output shaft 72 of the motor and a decelerate mechanism 73, and transmits a driving force to the driving shaft 9. The decelerate mechanism 73 includes a planet gear mechanism for transmitting the driving force from the output shaft 72.
The cylinder 20 extends along the top/bottom direction, and has the bottom connected to the nose 4 and the top disposed inside the body section 2A on the top. The cylinder 20 guides a movement of the piston 21 in the top/bottom direction, and restricts movements in directions other than the up/bottom direction.
The piston 21 is disposed in the cylinder 20, and is able to move back and forth between a top stop point on the top and a bottom stop point on the bottom in the cylinder 20. Furthermore,
The pressure chamber 2a is disposed above the cylinder 20 connecting through the cylinder 20 (i.e., above the top stop point of the piston 21). That is to say, a space is integrally formed by the cylinder 20 and the pressure chamber 2a above the piston 21. The pressure chamber 2a is filled with a compressed gas such as Nitrogen or the like so the piston 21 may be forced in the bottom direction by a pressure of the compressed gas.
As shown in
The blade 31 is a stick-like member extending along the top/bottom direction, which is connected to the bottom of the piston 21 and able to move together with the piston 21. When the blade 31 conducts reciprocating movements together with the piston 21 in the top/bottom direction, the nail N disposed on the nose 4 may be fired. The rack 31 is disposed on the bottom of the blade 31 and a lateral side of the blade 31.
The rack 30 is constituted by a plurality of teeth formed with a uniform pitch, and disposed on the bottom and the lateral side of the blade 31 along an axial direction of the blade 31. The rack 30 can engage with the pinion 32 to receive the driving force for guiding the movement of the blade 31 in the top direction. The guided section 37 is disposed below the rack 30.
The guided section 37 is disposed on the lateral side of the blade 31 and below the rack 30 to form a teeth row connected with the rack 30, and can engage with the roller 33. The guided section 37 is a section engaging with the roller 33 when the piston 21 is located at the top stop point. At this time, the pressure of the pressure chamber 2a is at the highest so a large loading is applied to the guided section 37. Accordingly, the guided section 37 needs to have high rigidity or strength. For that reason, the guided section 37 has a shape longer than the teeth of the rack 30 in the axial direction of the blade 31, and formed with a pitch different from that of the teeth of rack 30 (i.e., different pitches). The rack 30 and the guided section 37 may be a member integrally formed in one process or may be members respectively formed in different processes. Moreover, the rack 30 and the guided section 37 are equivalent to the engaging section in the invention.
The pinion 32 has teeth with the same pitch as the rack 30 and can engage with the rack 30. The pinion 32 has a shaft section connected to the driving shaft 9 in order to rotate together with the driving shaft 9 so the pinion 32 can receive the driving force from the driving shaft 9. The pinion 32 transmits the driving force to the rack 30 through the engagement with the rack 30. Further, the pinion 32 is connected with the cam 34.
The cam 34 shows a generally triangular shape protruding outwardly along a radial direction of the pinion 32. Specifically, the cam 34 is secured on the pinion 32 with one vertex of the generally rectangular shape formed as protrusion protruding along the radial direction of the pinion 32. Further, the roller 33 is rotatably supported by said protrusion.
The roller 33 shows a generally cylindrical shape extending along the front/rear direction. The roller 33 can rotate on the cam 34 with an axis extending along the front/rear direction as the center and can engage with the guided section 37. Specifically, the roller 33 has a teeth row formed with a shape different from the teeth of the pinion 32 and connected to the teeth of the pinion 32. Said teeth row is formed in a different pitch. The teeth row can engage with the rack 30 and the guided section 37 (i.e., the engaging section). The roller 33 has an elastomer containing an elastomer resin, such as rubber. The roller 33 is one example of the another end portion in the invention.
A channel 4a is formed in the nose 4 for the nail to pass through from the bottom of the housing 2 to a front end of the nose 4. The blade 31 may be inserted through the channel 4a so the blade 31 can fire the nail N disposed in the channel 4a when the blade 31 moves in the bottom direction. Further, a push rod 40 is disposed on the front end of the nose 4 and the driving machine 1 can drive the nail N only when the push rod 40 is pressed against a to-be-driven member. Furthermore, the nail N in the present embodiment is equivalent to the fastener in the invention.
The magazine 5 at the bottom of the housing 2 extends from the rear of the nose 4 in the rear direction to be connected with the bottom of the cell connection section 2D. The magazine 5 is disposed inside with a plurality of the nails N in bundles, and can supply the nails N into the channel 4a of the nose 4.
The pinion 32, the roller 33 and the cam 34 are equivalent to the engaged section in the invention. Further, the roller 33 and the cam 34 are equivalent to the roller mechanism in the invention. The roller 33, the cam 34, the driving shaft 9 and the pinion 32 are equivalent to the transmission mechanism in the invention.
Users can push the push rod 40 to a to-be-processed member and pull the trigger 10 in order to start operating the driving machine 1. After the trigger 10 is pulled, the driving section 7 starts operating so the motor 71 transmits the driving force to the driving shaft 9 via the output shaft 72 and the decelerate mechanism 73. After receiving the driving force via the driving shaft 9, the pinion 32 rotates together with the cam 34 in the clockwise direction in
After further rotation of the pinion 32, as shown by
After further rotation of the pinion 32 from the situation of
According to aforesaid structure, due to inclusion of the cam 34, the engaged section can include teeth with higher durability than the normal ones. Besides, the friction generated during the engagement with the guided section 37 may be reduced and the driving force may be smoothly transmitted by using the roller 33 in the engagement. As a result, wearing or damage on the guided section 37 and the roller 33 may be prevented, or the loading applied to the blade 31 may be increased to thereby increase the nailing force.
Besides, light weight, miniaturization, or reduction in manufacturing costs may be achieved for the driving machine 1 because aforesaid effect may be achieved using the relatively simple mechanism.
In addition, the guided section 37 has the large cross section because the rack 30 and the guided section 37 are formed in different pitches. As such, the guided section 37 is provided with the tolerable loading higher than the that of the teeth of the rack 30. As a result, wearing or damage on the guided section 37 may be prevented, and the loading applied to the blade 31 may be increased to thereby increase the nailing force. Moreover, because the cam 34 includes the roller 33, they can still smoothly engage even though the guided section 37 has a different pitch. The so-called “smoothly engage” refers to allowing a part of the guided section 37 to be processed into different members including certain manufacturing deviation, or allowing the pitch formed by the guided section 37 and the rack 30 to include certain manufacturing deviation. Besides, light weight, miniaturization, or reduction in manufacturing costs may be achieved for the driving machine because aforesaid effect may be achieved using the relatively simple mechanism.
In addition, the guided section 37 and the roller 33 can smoothly engage because the roller 33 is the elastomer and the roller 33 deforms during the engagement.
As described above, in the first embodiment, because the roller 33 can rotate and deform according to the shape of the guided section 37, the roller 33 and the guided section 37 can smoothly engage and disengage. However, the invention is not limited by the foregoing embodiment. Other embodiments allowing the roller 33 and the guided section 37 to smoothly engage and disengage are also provided in the invention.
The second embodiment is described using
In the second embodiment, when inspecting from the axial direction, an opening is formed in a center section of a pinion 132, and the opening prescribes four restriction sections 132a (
As shown in
As shown in
The driving shaft 109 engages with the cam 134 to transmit the driving force. That is to say, when the driving section 7 starts driving, the driving force is transmitted to the cam 134 from the driving shaft 9, and then the driving force is transmitted from the cam 134 to the pinion 132 via the elastomer 136.
Diagrams in
When the pinion 132 engages with the rack 30 so the blade 31 moves in the top direction (
After further rotation of the pinion 132 and the cam 134, the roller 33 engages with the guided section 37 (
After further rotation of the pinion 132 and the cam 134, the blade 31 moves in the top direction (
When excessive loading is applied to the pinion 132, the restriction section 132a is in contact with the cam restriction section 135A so excessive shifting of the pinion 132 relative to the cam 134 and damage on the elastomer 136 may be prevented.
It is noted that, the roller 33 includes the elastomer in the first embodiment. However, a hard member may also be used in the second embodiment rather than being limited to the use of the elastomer. Even if aforesaid structure is adopted, the same effect may still be obtained since the elastomer 136 is provided between the pinion 132 and the cam 134.
As described above, in the second embodiment, because the pinion 132 can shift relative to the cam 134 in the circumferential direction, not only can the pinion 132 be smoothly engaging with the rack 30, the roller 33 can also smoothly engage with the guided section 37. Further, excessive deformation of the pinion 132 and damage on the elastomer 136 may be prevented by the restriction section 132a and the cam restriction section 135A.
The third embodiment is described using
As shown in
As shown in
As shown in
The driving shaft 209 engages with the pinion 232 to transmit the driving force to the pinion 232. That is to say, when the driving section 7 starts driving, the driving force is transmitted from the driving shaft 209 to the pinion 232, and then the driving force is transmitted from the pinion 232 to the cam 234 via the elastomer 236.
Diagrams in
When the roller 33 engages with the guided section 37 (
After further rotation of the pinion 232 and the cam 234, the blade 31 shifts in the top direction (
It is noted that, the roller 33 includes the elastomer in the first embodiment. However, a hard member may also be used in the third embodiment. Even if aforesaid structure is adopted, the same effect may still be obtained since the elastomer 236 is provided between the pinion 232 and the cam 234.
As described above, in the third embodiment, because the cam 234 can shift relative to the pinion 232 in the circumferential direction, the roller 33 and the guided section 37 can smoothly engage.
Diagrams in
A pinion 332 shown in
In the foregoing embodiments, the elastomer resin, such as rubber, is used as the elastomer between the pinion and the cam. However, the invention is not limited to such implementation, any material or structure with desired resilience coefficient or spring constant may also be adopted. For example, in addition to elastic materials (the elastic resin) such has rubber, a structure that functions as the so-called “gas spring” (a structure that utilizing a resilient force of a gas by sealing the gas into an enclosed space, for example) also falls within the scope of the invention. Further, a flat spring or a coil spring containing a metal sheet or a resin sheet may also be used as the example for structurally constituting the elastomer, and specific examples thereof same are provided as follows.
Shapes of the pinion 332 and the cam 234 shown in
A pinion 632 shown in
Furthermore, in the foregoing embodiments, the elastomer is provided between the pinion and the cam. Nonetheless, the invention is not limited to the above, and the elastomer may also be provided between the driving shaft and the pinion or the cam instead.
For example, in the first embodiment, the elastomer my also be set to be provided between the driving shaft 9 and the pinion 32. According to aforesaid structure, because the pinion 32 and the cam 34 can shift in the circumferential direction, the pinion 32 and the rack 30 can smoothly engage and the guided section 37 and the roller 33 can also smoothly engage and disengage.
Further, in the second embodiment, the elastomer may also be set to be further provided between the driving shaft 109 and the cam 134. If aforesaid structure is set, the cam 134 can shift relative to the driving shaft 109 in the circumferential direction so the guided section 37 and the roller 33 can smoothly engage and disengage. Therefore, the friction during the engagement of the pinion 132 and the rack 30 or during the engagement of the roller 33 and the guided section 37 may be prevented or reduced so they can smoothly engage even though the pitch of the rack 30 includes the deviation or the rack has a different pitch. As a result, wearing or damage on the engaged section may be prevented, or the loading applied to the blade may be increased to thereby increase the nailing force. Besides, light weight, miniaturization, or reduction in manufacturing costs may be achieved for the driving machine 1 because aforesaid effect may be achieved using the relatively simple mechanism.
Further, the cam 134 may also serve as a front end portion of the driving shaft 109 to be integrally formed with the driving shaft 109. In this case, because the cam restriction section 135A is in contact with the restriction section 132a so a relative shifting of the pinion 132 relative to the circumferential direction of the driving shaft is restricted. Such implementation is also able to prevent excessive shifting of the pinion 132 or plastic deformation and damage on the elastomer 136.
Next, a driving machine 701 of the fourth embodiment is described using
As shown in
The tube section 711A is a cylinder shape extending along the front/rear direction and secured on the inner wall of the driving section accommodating section 2C. A plurality of accommodating slots 711a are formed on an inner circumference surface of the tube section 711A. The accommodating slots 711a are slots formed caving outwardly from the inner circumference surface of the tube section 711A along the radial direction and extending in the front/rear direction. Each of the accommodating slots 711a is accommodated with one of the rollers 711B.
The roller 711B is a needle-shaped roll extending in the front/rear direction, which may be accommodated in the accommodating slot 711a when rotating with its axis as the center and being in contact with the driving shaft 9. Further, in the accommodating slot 711a, the roller 711B is unable to move in the front/rear direction but move along the circumferential direction for a prescribed quantity. In the present embodiment, the prescribed quantity is a length substantially identical to a diameter of the roller 711B.
A depth of the accommodating slot 711a gradually becomes deeper from an upstream side to a downstream side of the accommodating slot 711a in the direction of the forward rotation of the driving shaft 9, a depth of an upstream side edge section is shorter than the diameter of the roller 711B, and a depth of a downstream side edge section is substantially identical to the diameter of the roller 711B. In addition, a force member (i.e., a spring 711C) is provided between the roller 711B accommodated in the accommodating slot 711a and the downstream side edge section of the accommodating slot 711a, and thus the roller 711B is forced from the downstream side edge section to the upstream side edge section.
Here, functions of the one-way clutch 711 are described as follows. After the forward rotation is started by the driving shaft 9, each of the rollers 711B in contact with an outer circumference surface of the driving shaft 9 rotates with its axis as the center inside the respective one of the accommodating slots 711a, and starts to move from the upstream side edge section to the downstream side edge section in the direction of the forward rotation of the driving shaft 9 while withstanding the force from the spring 711C. If the roller 711B is located on the downstream side edge section at the deepest of the accommodating slot 711a, a pressure on a contact surface of the outer circumference surface of the driving shaft 9 and the roller 711B may be reduced. In this case, the friction between each of the rollers 711B and the outer circumference surface of the driving shaft 9 caused by the pressure on the contact surface does not interfere the forward rotation of the driving shaft 9 relative to the tube section 711A. In such case, the driving shaft 9 is able to continue the forward rotation. That is to say, the one-way clutch 711 allows the driving shaft 9 and the pinion 32 to rotate forwardly.
On the other hand, after the backward rotation is started by the driving shaft 9, each of the rollers 711B rotates with its axis as the center inside the respective one of the accommodating slots 711a, and starts to move from the downstream side edge section to the upstream side edge section in the direction of the forward rotation of the driving shaft 9 while withstanding the force from the force member (i.e., the spring 711C). If the roller 711B is located on the downstream side edge section at the shallowest of the accommodating slot 711a, the pressure on the contact surface of the outer circumference surface of the driving shaft 9 and the roller 711B becomes the greatest. In this case, the friction between each roller 711B and the outer circumference surface of the driving shaft 9 caused by the pressure on the contact surface becomes the greatest so the driving shaft 9 is unable to rotate backwardly relative to the tube section 711A (the situation shown by
In this way, in the driving machine 701 according to the fourth embodiment, the backward rotation of the driving shaft 9 and the pinion 32 may the restricted because of the one-way clutch 711 disposed on the driving section accommodating section 2C (i.e., between the housing 2 and the driving shaft 9). As a result, a usability of the driving machine 701 may be improved.
Specifically, in the middle of moving the piston 21 and the blade 31 from the bottom stop point to the top stop point (e.g., the situation shown by
However, due to inclusion of the one-way clutch 711, the driving machine 701 can restrict the backward rotation of the driving shaft 9 and the pinion 32 and can restrict the movement of the piston 21 and the blade 31 in the bottom direction. In this way, the aforementioned problems are solved so the finishing grade may be favorably maintained and the usability may be improved.
The driving machine of the invention is not limited by the foregoing embodiments, and various modifications may be made without changing the spirit in the scope of the subject matters in the invention.
In the foregoing embodiments, the roller 33 is connected to the pinion or the cam. Nonetheless, the invention is not limited to the above. The roller 33 may also be set to be disposed on the rack 30 or the guided section 37. If aforesaid structure is set, the rack 30 (or the guided section 37) and the cam (or the pinion) can smoothly engage or disengage. Moreover, in such case, the roller 33 and the rack 30 (or the roller 33 and the guided section 37) are equivalent to the roller mechanism in the invention. Furthermore, in such case, the pinion and the cam are equivalent to the engaged section in the invention, whereas the rack 30, the guided section 37 and the roller 33 are equivalent to the engaging section in the invention.
In the foregoing embodiments, the roller is connected to the pinion or the cam. Nonetheless, the invention is not limited to the above, and it is also possible to use a structure not disposed with the roller. If aforesaid structure is set, because the elastomer is provided and the elastomer can deform, the guided section 37 and the cam can still smoothly engage and disengage. Therefore, the guided section 37 and the cam can still smoothly engage because the friction during the engagement of the cam and the guided section 37 may be prevented or reduced even though the pitch of the guided section 37 and the rack 30 includes the deviation or the rack has a different pitch. Besides, light weight, miniaturization, or reduction in manufacturing costs may be achieved for the driving machine 1 because aforesaid effect may be achieved using the relatively simple mechanism.
In the foregoing embodiments, the driving machine 1 that drives the nail as the fastener is illustrated as one example of the driving machine, but the invention is not limited thereto. The invention may be applied to all tools that can serve as the driving machine and fire mechanical joint fittings including nails, screws, staples, etc. Furthermore, general fasteners in the related art, such as screws, nails, drawing pins, rivets, staples, etc., may also be considered as the specific example of the fastener.
Although the driving section 7 of electric type having the motor 71 is used as one example, the invention is not limited thereto. The invention is also suitable in other driving machines with other driving method including solenoid or the like.
In the foregoing embodiments, the gas spring using the compressed gas is illustrated as one example of the force member serving as the blade for driving the fastener, but the invention is not limited thereto. For example, it is obvious for persons skilled in the art that the invention may be applied to other force members such as the coil spring and the like.
Although the one-way clutch 711 having the rollers 711B is used in the fourth embodiment, a ball-type one-way clutch having balls and ball slots formed on an inner circumference surface may also be used as long as the structure restricting the backward rotation and allowing the forward rotation for the driving shaft 9 and the pinion 32 may be provided.
It will be apparent to those skilled in the art that various modifications and variations can be made to the structure of the present invention without departing from the scope or spirit of the invention. In view of the foregoing, it is intended that the present invention cover modifications and variations of this invention provided they fall within the scope of the following claims and their equivalents.
Number | Date | Country | Kind |
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2014-112176 | May 2014 | JP | national |
2014-201453 | Sep 2014 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2015/064753 | 5/22/2015 | WO | 00 |