The present invention relates to a driver, and more particularly, to a driver provided with a weight.
A conventional driver is known in the art. The driving includes a plunger 7 for striking a nail, a nose portion 3 formed with an ejection hole through which the nail hit by the plunger 7 is ejected, a spring configured to urge the plunger 7 in an impact direction, and a motor used for accumulating an resilient energy in the spring (See Patent Literature 1). According to such driver, driving force of the motor causes the spring to accumulate the resilient energy. Release of the resilient energy causes the plunger 7 to be accelerated in the impact direction, thereby striking the nail to a workpiece such as boards made of wood or gypsum. The striking operation is performed with the ejection hole being in abutment with the workpiece.
Patent Literature 1: Japanese Patent Application Publication 2011-56613
In the above driver, when the plunger 7 is accelerated in the impacting direction, a reaction force is generated and applied to a driver main body by the reaction against the acceleration of the plunger 7. Therefore, the ejection hole is moved away from the workpiece. Thus, it is difficult to strike the nail in a direction perpendicular to the surface of the workpiece, while maintaining a posture of the driver main body. Alternatively, the operation is a heavy burden to the user. In order to restrict the reaction, the user presses the ejection hole against the workpiece excessively, which would lead to a damage to the workpiece. Accordingly finishing to the workpiece may be degraded.
It is therefore, an object of the present invention is to provide a driver capable of reducing reactive force occurring in the driver main body, with enhancing workability, and providing desirable finishing.
In order to solve the above problems, the invention provides a driver comprising: a nose portion 3 provided in a housing 2 and extending in a longitudinal direction, the nose portion being configured to allow a fastener to pass therethrough; a plunger 7 configured to move in an impact direction parallel to the longitudinal direction to impact the fastener through the nose portion 3; a weight 8; and a resilient member configured to be compressed by a motor in the longitudinal direction, a release of the compression in the resilient member causing the plunger 7 to move in the impact direction, while causing the weight 8 to move in a counter-impact direction which is away from the plunger. The resilient member is provided between the plunger 7 and the weight 8, the resilient member having one end portion and another end portion in the longitudinal direction, the one end portion being configured to urge the plunger 7, and the another end portion being configured to urge the weight 8.
According to the above configuration, for driving the fastener by the nail fastening driver 1, the resilient member is compressed by the motor in the longitudinal direction. Then, when the compression is released, the resilient energy accumulated in the resilient member causes the plunger 7 to move in the impact direction and then strike the fastener into the workpiece, and causes the weight 8 to move in a counter-impact direction. The forces generated by the movement of the plunger 7 and the weight 8 are cancelled to each other, so that a reaction force does not directly exert on the housing 2. Accordingly, the lifting up of the housing 2 from the workpiece is prevented. The strike operation can be finished, while maintaining orientation of the nose portion 3 to the workpiece, thereby improving workability of the driver.
Further, during driving the fastener, the housing 2 is not lifted up from the workpiece. Therefore, a user can perform the strike operation without excessively urging the nose portion 3 against the workpiece. This can reduce generation of pressure mark on the surface of the workpiece, so that finishing is improved after striking the fastener to the workpiece.
Further, the resilient member is provided between the plunger 7 and the weight 8. Accordingly, the configuration is simple, and the driver can be manufactured at a low cost.
Further, the resilient member has the one end in the longitudinal direction which urges only the plunger 7, and the another end which urges only the weight 8. Therefore, lifting up of the housing 2 from the workpiece during the strike operation can be restrained. Further, the stroke of the plunger can be ensured by properly determining the weight of the plunger 7 and the weight 8.
Preferably, the resilient member comprises a single coil spring. The single coil spring allows each of the plunger 7 and the weight 8 to be movable. Therefore, the number of parts constituting the driver can be reduced, and the driver can be manufacture at a low cost.
Preferably, the driver further comprises a drive mechanism configured to cause a motor to compress the resilient member in the longitudinal direction. The drive mechanism is configured to release compression of the resilient member to cause the plunger 7 to start moving in the impact direction, and simultaneously cause the weight 8 to start moving in the counter-impact direction.
With the above structure, the force generated by the movement of the plunger 7 in the impact direction is cancelled with the force generated by the movement of the weight 8 in the counter-impact direction, so that a reaction force is not exerted on the housing 2 directly. Accordingly, a user can perform the strike operation without pressing the nose portion 3 against the workpiece excessively in an attempt to avoid lifting up the housing 2. Thus, the generation of a pressure mark on the workpiece can be reduced, and finishing after striking the fastener into the workpiece can be improved.
Preferably, the driver further comprises a drive mechanism configured to cause the motor to compress the resilient member in the longitudinal direction. The drive mechanism is configured to release compression of the resilient member from the another end portion to cause the weight 8 to start moving in the counter-impact direction, and then the drive mechanism is configured to release compression of the resilient member from the one end portion to cause the plunger 7 to move in the impact direction.
With the above configuration, as the weight 8 firstly starts moving in the counter impact direction, a reaction by the movement of the weight 8 urges the nose portion 3 of the housing 2 to be directed to the workpiece in the impact direction. Accordingly, this operation prevents the nose portion 3 from being deviated from a target position for the fastener. When the plunger 7 starts moving in the impact direction, the force generated by the movement of the weight 8 in the counter-impact direction is cancelled with the force generated by the movement of the plunger 7 in the impact direction. As a result, urging of the housing 2 to the workpiece is ceased. Accordingly, when the fastener is to be driven to a side surface of the workpiece or the fastener is oriented upward, the strike operation can be performed while preventing the nose portion 3 from being deviated from the target strike position on the workpiece without urging the nose portion 3 to the workpiece excessively. Further, the generation of a pressure mark on the workpiece can be reduced, and finishing after striking the fastener into the workpiece can be improved.
Preferably, the driver further comprises a weight restriction member provided in the housing 2 and configured to restrict further movement of the weight 8 in the counter-impact direction. The weight 8 is configured to be in abutment with the weight restriction member after the plunger 7 strikes the fastener.
With the above structure, as the weight 8 is in abutment with the restriction member after the striking of the fastener, the force generated by the movement of the weight 8 in the counter-impact direction after the striking of the fastener exerts on the housing 2 as a reaction force. The reaction force lifts up the housing 2 from the workpiece after the strike operation is over, so that finishing to the surface of the workpiece can be improved.
Preferably, the driver further comprises a plunger restriction member provided in the housing 2 and configured to restrict movement of the plunger 7 in the impact direction. The plunger and the weight are provided in the housing in such a manner that a moving distance of the plunger 7 to the plunger restriction member is set longer than a moving distance of the weight 8 to the weight restriction member.
With the above structure, moving distance of the weight can be shortened while obtaining sufficient stroke which is necessary for striking the fastener, and accordingly, a compact housing 2 of the driver can result.
In the driver according to the present invention, the force generated by the movement of the plunger 7 in the impact direction is cancelled with the force generated by the movement of the weight 8 in the counter-impact direction. Accordingly, the present invention exhibits the advantages that the action of the reaction force to the housing 2 can be suppressed.
[
A side view of a nail fastening driver according to the invention in which a plunger 7 is positioned at a bottom dead center.
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A side view of the nail fastening driver in which the plunger 7 shown in
[
A perspective view of the plunger 7 of the nail fastening driver shown in
[
A perspective view of a weight 8 of the nail fastening driver shown in
[
A perspective view of the nail fastening driver shown in
[
Figures (a) to (h) are time series chart showing operations of a drive mechanism, a plunger 7, and a weight 8 of the nail fastening driver shown in
[
Figures (a) to (d) are time series chart showing conditions of the plunger 7, and the weight 8 of the nail fastening driver shown in
[
Figures (a) to (i) are time series chart showing operations of the drive mechanism, the plunger 7, and the weight 8 of the nail fastening driver shown in
[
Figures (a) to (d) are time series chart showing operations of the drive mechanism, the plunger 7, and the weight 8 of the nail fastening driver shown in
[
Figures (e) to (g) are time series chart showing operations subsequent to the movements of the drive mechanism, the plunger 7, and the weight 8 of the nail fastening driver shown in
An electric nail fastening driver 1 to which the present invention is applied will be described. The nail fastening driver 1 is an electrically powered tool used to drive a nail as a fastener into a workpiece W such as boards made of wood or gypsum.
The nail fastening driver 1 primarily includes a housing 2 for accommodating a motor, a nose portion 3 provided in the housing 2 for ejecting the nail, and a magazine 4 for supplying the nail to the nose portion 3. Incidentally, in
As shown in
The motor housing 22 accommodates therein the motor 5 and a deceleration mechanism 50. The motor 5 has a rotation shaft 5A extending in the frontward/rearward direction and is located in the rear portion of the motor housing 22.
The deceleration mechanism 50 is connected to the rotation shaft 5A at a position in front of the motor 5. The deceleration mechanism 50 is configured of a planetary gear mechanism including two planet gears 50A arranged around the rotation shaft 5A, a ring gear 50B arranged coaxially with the rotation shaft 5A, and a carrier 50C provided with a carrier gear 50D rotating coaxially with the rotation shaft 5A. The planet gear 50A is rotatably supported to the carrier 50C to orbitally move about the rotation shaft 5A. The orbital movement of the planet gear 50A decelerates the rotation speed of the rotation shaft 5A. Further, the orbital movement of the rotation shaft 5A causes rotation of the carrier gear 50D through the carrier 50C.
The handle portion 23 is configured to be gripped by a user when the user uses the nail fastening driver 1. A trigger 23A is provided at a front lower portion of the handle portion 23 for starting the supply of electric power to the motor 5. A battery 23B for supplying electric power to the motor 5 is detachably attached to the rear end portion of the handle portion 23.
A guide shaft 10 is provided within the main body 21 in such a manner that its longitudinal direction is oriented parallel to the upward/downward direction. The plunger 7, the coil spring 9, and the weight 8 allow the guide shaft 10 to be inserted therethrough in this order upward in the main body 21. The main body 21 further includes the drive mechanism 6.
The drive mechanism 6 is provided between the motor 5 and the guide shaft 10 in the main body 21, and configured of a driving gear 61, a gear holder 62, a first gear 63, and a second gear 64. The gear holder 62 is fixed to the main body 21, and includes a support shaft 62A and a support shaft 62B. The support shaft 62A protrudes frontward from the lower portion of the gear holder 62. The support shaft 62B protrudes frontward at a position above the support shaft 62A.
The first gear 63 is rotatably supported to the support shaft 62A, and is connected to the deceleration mechanism 50 through the driving gear 61. The rotation of the driving gear 61 causes rotation of the first gear 63 in a counterclockwise direction as viewed from the front. The first gear 63 is provided with a first roller-cam 63A, a second roller-cam 63B, and a third roller-cam 63C which are positioned at an imaginary circle whose center is coincident with an axis of the first gear 63 and arrayed in the circumferential direction at predetermined intervals and protrude frontward, respectively. The protruding length of each of the first roller-cam 63A, the second roller-cam 63B, and the third roller-cam 63C in the axial direction is different from each other.
The second gear 64 is rotatably supported to the second gear 64 and meshingly engaged with the first gear 63. The rotation of the first gear 63 causes rotation of the second gear 64 in a clockwise direction as viewed from the front. The second gear 64 has a first roller-cam 64A and a second roller-cam 64B which are positioned at an imaginary circle whose center is coincident with an axis of the second gear 64 and arrayed in the circumferential direction at intervals and protrude frontward, respectively. The protruding length of each of the first roller-cam 64A and the second roller-cam 64B in the axial direction is different from each other.
The guide shaft 10 has one end and the other end in the longitudinal direction, the one end being fixed to the inside of the upper end portion of the main body 21, and the other end being fixed to the inside of the lower end portion of the main body 21. A weight bumper 11 with which the weight 8 is abuttable is attached to one end portion of the guide shaft 10 as a weight restriction member. The weight bumper 11 is adapted to absorb the impact generated when the weight 8 collides against the housing 2. A plunger bumper 12 with which the plunger 7 is abuttable is provided at the other end portion of the guide shaft 10 as the plunger restriction member. The plunger bumper 12 is adapted to absorb the impact generated when the plunger 7 strikes the fastener.
The plunger 7 is configured to strike the fastener in an impact direction which is parallel to the longitudinal direction of the guide shaft 10, and allows the guide shaft 10 to be inserted therethrough. As shown in
The first abutment portion 71A protrudes rearward from the outer peripheral surface of the engaging portion 7D. The lower surface of the first abutment portion 71A is abuttable with the first roller-cam 63A of the first gear 63. The second abutment portion 71B also has a flat plate shape and protrudes rearward from the outer peripheral surface of the engaging portion 7D. The second abutment portion 71B is positioned lower than the first abutment portion 71A and is abuttable with the second roller-cam 63B of the first gear 63. The third abutment portion 71C also has a flat plate shape and protrudes rearward from the outer peripheral surface of the engaging portion 7D at a position below the second abutment portion 71B. The second abutment portion 71B is abuttable with the third roller-cam 63C of the first gear 63.
The rod 13 for directly striking the nail is made from metal, and is attached to the rod attachment portion 7C, and is slidably movable within the nose portion 3.
The weight 8 is adapted to receive a reaction force generated when the plunger 7 strikes, and functions as a reaction weight, and made from a metal. The weight 8 allows the guide shaft 10 to be inserted therethrough so as to be movable in a counter-impact direction which is away from the plunger 7. As shown in
The first abutment portion 81A protrudes rearward from the outer peripheral surface of the weight 8. The upper surface of the first abutment portion 81A is abuttable with the first roller-cam 64A of the second gear 64. The second abutment portion 81B has a plate shape and protrudes rearward from the outer peripheral surface of the weight 8. The second abutment portion 81B is positioned above the first abutment portion 81A, and is abuttable with the second roller-cam 64B of the second gear 64.
The coil spring 9 is a single coil spring which accumulates an resilient energy when being compressed. When its compression is released, the accumulated energy is released. The coil spring 9 allows the guide shaft 10 to be inserted therethrough, and is positioned between the weight 8 and the plunger 7. The other end portion of the coil spring 9 is fitted with the outer peripheral surface of the inner sleeve portion 8A of the weight 8, and urges the weight 8 to the counter-impact direction. On the other hand, one end portion of the coil spring 9 is in abutment with the abutment portion 7E of the plunger 7 to urge the plunger 7 in the impact direction. When the coil spring 9 is in the compressed condition, the coil spring 9 urges the plunger 7 downward, and urges the weight 8 upward. When the compression of the coil spring 9 is released, the resilient energy accumulated in the coil spring 9 urges the plunger 7 to move downward along the guide shaft 10, and urges the weight 8 to move upward. The coil spring 9 corresponds to a resiliently deformable member.
As shown in
The magazine 4 extends rearward from the rear portion of the nose portion 3 and accommodates therein a plurality of nails. The magazine 4 has a nail supplying mechanism for supplying the nail from the magazine 4 to the ejection hole 3a of the nose portion 3.
Operation of the nail fastening driver 1 will be described below.
Before the operation, in other words, in the initial state of the nail fastening driver 1, as shown in
In the initial state, as shown in
The operation of each of the drive mechanism 6, the plunger 7, the weight 8, and the coil spring 9 will be described referring to
When the nail fastening driver 1 starts the operation, power is transferred from the motor 5 to the drive mechanism 6, and the first gear 63 starts rotating in the counterclockwise direction. Simultaneously, the second gear 64 starts rotating in the clockwise direction. When the rotation angle is zero, as shown in
Next, as shown in
When the rotation angle comes to 85 degrees, as shown in
When the rotation angle reaches 220 degrees, as show in
In the state shown in
In other words, because the compression of the coil spring 9 is released as shown in
After that, the first gear 63 and the second gear 64 maintain rotating until the rotation angle reaches 360 degrees. Therefore, one cycle for the striking operation is completed.
According to the nail fastening driver 1 thus constructed, for striking a nail to a workpiece W, the plunger 7 which has been accelerated by the accumulated resilient energy in the coil spring 9 strikes the nail into the workpiece W. After striking the nail, because the energy which has not been used for striking the nail is transferred to the housing 2 through the plunger 7 and the plunger bumper 12, the housing 2 is urged to be moved in the direction toward the workpiece W. On the other hand, because the weight 8 is hit to the weight bumper 11 at the same time, the housing 2 is urged to be moved upward (the direction opposite to the direction toward the workpiece W). Accordingly, the movement of the power tool body (the nail fastening driver 1) due to the impact after striking the nail can be prevented.
Further, because the coil spring 9 allows the guide shaft 10 to be inserted therethrough between the plunger 7 and the weight 8, direct fixing of the coil spring to the housing 2 is not necessary. This structure makes the configuration of the nail fastening driver 1 to be simple.
Further, the stroke of the plunger 7, so-called, the distance between the bottom dead center L1 and the top dead center L2 can be changed by modifying the configurations of the first gear 63 and the second gear 64 constituting the drive mechanism 6, or by modifying positions of the first roller-cam 63A to third roller-cam 63C, the first roller-cam 64A, and the second roller-cam 64B provided on each gear, or by modifying positional relationship between the first roller-cam 63A, the second roller-cam 63B, and the third roller-cam 63C of the first gear 63 and the first roller-cam 64A and the second roller-cam 64B of the second gear 64, or modifying the shapes and/or weights of the plunger 7 and the weight 8 in a proper manner. Further, the moving speeds of the plunger 7 and the weight 8 can be set to different values. In a similar manner, the stroke of the weight 8, so-called, the distance between the topmost point L4 and the lowest point L3 can be changed. As a result, sufficient stroke of the plunger 7 which is necessary to strike a nail can be obtained, and the stroke of the weight 8 can be shortened. Therefore, the size of the nail fastening driver 1 in the upward/downward direction can be shortened to provide a compact driver.
Incidentally, in this embodiment, the weight 8 is heavier than the plunger 7, and the moving distance of the plunger 7 is set longer than the moving distance of the weight 8 during the striking operation. However, considering the weight relationship between the weight 8 and the plunger 7, the weight 8 and the plunger 7 are set to be struck on the weight bumper 11 and the plunger bumper 12, respectively, approximately simultaneously.
Next, a second embodiment will be described as follows. In the second embodiment, the compression of the coil spring 9 by the weight 8 is first released, and then the compression of the coil spring 9 by the plunger 7 is released. After the plunger 7 strikes a nail, the plunger 7 is first caused to impact on the plunger bumper 12, and then the weight 8 is caused to impact on the weight bumper 11, thereby ceasing the movement of the plunger 7 and the weight 8.
According to this operation, the weight 8 is separated from the housing 2, which prevents the load generated by the expansion of the coil spring 9 from being transferred to the housing 2. This operation prevents the tool body (the nail fastening driver 1) from being lifted upward.
In the state shown in
When the rotation angle reaches 277 degrees, as the abutment between the third roller-cam 63C of the first gear 63 and the third abutment portion 71C is released as shown in
As shown in
Thereafter, the first gear 63 and the second gear 64 are kept rotating until the rotation angle reaches 360 degree.
According to the above-described operation of the nail fastening driver 1, before the plunger 7 is driven for the strike, the compression of the coil spring 9 is released from the weight 8 side and then the weight 8 is caused to start moving. Therefore, a force directing to the workpiece acts on the housing 2. As a result, the nail is driven to a desired position precisely without excessively urging the housing 2 toward the workpiece W more than necessary.
Incidentally, in this embodiment, the weight 8 is heavier than the plunger 7, the moving distance of the plunger 7 during the strike operation is longer than the moving distance of the weight 8, and the weight 8 is started moving earlier than the plunger 7. However, considering the weight relationship between the weight 8 and the plunger 7, the weight 8 and the plunger 7 are set to be hit on the weight bumper 11 and the plunger bumper 12, respectively, at the same time.
Further, the timing is adjusted in such a manner that the weight 8 impacts on the weight bumper 11 after the plunger 7 impacts on the plunger bumper 12. Due to the collision of the weight 8 to the weight bumper 11, a force in a direction away from the workpiece W acts on the housing 2. Accordingly, a roughening to a surface of the workpiece W due to the reaction force generated by the striking can be prevented.
The striking timing of the weight 8 and the plunger 7 and time period required to impinge on the bumper may be changed by properly modifying the configuration of the first gear 63 and the second gear 64 constituting the drive mechanism 6, by modifying the positions of the first roller-cam 63A to third roller-cam 63C, the first roller-cam 64A, the second roller-cam 64B positioned on each gear, by modifying positional relationship between the first roller-cam 63A, the second roller-cam 63B, and the third roller-cam 63C of the first gear 63, and the first roller-cam 64A, the second roller-cam 64B of the second gear 64, and by modifying the shapes and weights of the plunger 7 and the weight 8.
The distance between the top dead center and the bottom dead center of the plunger 7 may be properly determined in accordance with the length of the nail.
Further, in this embodiment, the weight of the plunger 7 is about 50 g, and the weight of the weight 8 is about 175 g. The weight ratio may be preferably about 1 to 4, and more preferably not less than 1 to 4.
Incidentally, the present invention may be applied to any type of electric power tool in which the coil spring 9 is provided between the plunger 7 and the weight 8 along the guide shaft, and the coil spring 9 is configured to urge the plunger 7 and the weight 8, and the coil spring 9 is compressed by the plunger 7 and the weight 8 to accumulate an resilient energy in the coil spring 9 for performing intended operation.
Further, in the above embodiments, the coil spring 9 is used as the resiliently deformable member. Alternatively, any type of resilient member other than the coil spring can be used as long as the resilient member can urge the plunger 7 in the impact direction and the weight 8 in the counter-impact direction.
Number | Date | Country | Kind |
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2014-174400 | Aug 2014 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2015/073534 | 8/21/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2016/031716 | 3/3/2016 | WO | A |
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