1. Field of the Invention
The present invention relates to a transmission mechanism for an electrical nail gun, and more particularly to a transmission mechanism in which a solenoid is received in a cylinder of a flywheel, a clutch is located between the cylinder and an end side of a driving wheel, a magnetic field is produced by activating the solenoid to control engagement or disengagement of the driving wheel to transmit kinetic energy of the rotary flywheel.
2. Description of Related Art
An electrical nail gun is a type of tool used to drive nails into wood or some other kind of material. Usually, there is a battery pack or an AC electrical power source in a housing of the electrical nail gun to provide electrical power to a motor, thereby rotating the motor. A rotary kinetic energy of the motor is transformed into a linear kinetic energy by a transmission mechanism to drive a strike bar to impact nails.
Among a more advanced technology, many US patents, such as U.S. Pat. No. 6,607,111 and U.S. Pat. No. 6,669,072 and so on, teach a flywheel driven by a DC motor, a clutch assembly being capable of linear movement by traction of a wire disposed on an axis of a solenoid. The clutch assembly has a wire drum and connects to a driving stand via at least a wire. When a nail gun is driven by a user, the clutch assembly is moved along an axis direction to mesh with a flywheel which is rotating, thereby rotating the clutch assembly. Therefore, a rotary kinetic energy is transformed into a linear kinetic energy of the strike bar to then impact nails via traction of the wire. However, the structure of the clutch assembly is complicated due to too many components. The solenoid is disposed in the housing away from the flywheel, therefore, it is a disadvantage to save configuration room.
In addition, a number of patents, such as U.S.P 20050218177, WO No. 2005097428, and EP No. 1582300 and so on, teach a driver produced by a solenoid. The driver linearly pushes a swing arm forming a roller to swing. A driving stand of a stroke bar is pushed by the roller to urge the driving stand to mesh with a rotating flywheel. Thus, a rotary kinetic energy of the flywheel is transformed into a linear kinetic energy of a stroke bar to impact a nail. Wherein, the roller, the driving stand, and the flywheel cooperatively form a clutch assembly being capable of engagement or disengagement. However, during a long-term use, an abrasion may be produced by friction between the roller, the driving stand, and the flywheel to thereby broaden mesh clearance. When the driving stand of the stroke bar is pushed by the roller towards the flywheel to mesh with the flywheel, a component acting force is produced not along a direction of impacting the nail due to clearance, thereby affecting safety and stability as the driving stand is driving the stroke bar to impact the nail. Furthermore, the solenoid is disposed in the housing away from the flywheel or the clutch assembly; therefore, it is a disadvantage to save configuration room. Accordingly, the above-mentioned problems need to be further improved.
What is needed, therefore, is to provide a transmission mechanism configured for an electrical nail gun, which simplify a clutch assembly in a previous technology, save space for a solenoid, and overcome not to generate a component force not along stroke nail direction during long-term use of the nail gun.
An object and effect of the present invention is carried out through the following technology means. The transmission mechanism for an electrical nail gun of the present invention includes a rotary transmission unit and a linear transmission unit in a housing of the electrical nail gun. The rotary transmission unit includes:
a motor driven by electricity;
a flywheel driven by the motor, the flywheel pivotally mounted on a stop shaft, a cylinder extended from a side of the flywheel thereon and made of magnetic material, and the cylinder defining a ring-shaped receiving chamber therein;
a solenoid activated by electricity and buried in the receiving chamber, wherein a magnetic conductivity loop is constructed around the solenoid to produce the magnetic field when the solenoid is activated; and
a moveable driving wheel rotatably disposed between an engagement position and a disengagement position adjacent to an end side of the cylinder, wherein two opposite slantwise end surfaces are respectively formed on the cylinder and the driving wheel to be used as a clutch;
wherein the driving wheel is attracted to move to the engagement position to be driven by the flywheel, thereby driving the linear transmission unit to impact a nail when the solenoid is activated by electricity, and the driving wheel returns to the disengagement position to disengage from the flywheel, thereby stopping driving the linear transmission unit when the solenoid is demagnetized.
In addition, the present invention includes a ring-shaped bearing. The ring-shaped bearing is made of a magnetic material, and securely mounted on the stop shaft. The solenoid is wrapped around an insulated ring stand, and securely disposed on the stop shaft via the bearing. Alternatively, the ring stand is directly mounted on the stop shaft without the bearing.
The present invention further includes a ring-shaped traction stand made of a magnetic material. The ring-shaped traction stand is moveably and pivotally mounted on the stop shaft, and the driving wheel is disposed on the traction stand. Wherein an end of the traction stand is formed to have at least a protruding block which is used to push the driving wheel to move towards the cylinder. Besides, the traction stand may be replaced by a ring-shaped disk stand made of magnetic material. The disk stand is securely mounted on the stop shaft, and a plurality of rolling posts is accommodated around the disk stand. The driving wheel is moveably and pivotally disposed on the rolling posts.
The present invention further includes an elastic member. The elastic member is configured for exerting an acting force on the driving wheel, thereby pushing the driving wheel from the engagement position to the disengagement position, and the acting force should be less than an applied force which the magnetic field attracts the driving wheel to move. The elastic member is disposed between the ring-shaped bearing securely mounted on the stop shaft and the traction stand moveably and pivotally attached to the stop shaft. Besides, the elastic member is disposed between the ring-shaped disk stand and the driving wheel when the traction stand is replaced by the disk stand.
Furthermore, the driving wheel is substantially a gear wheel, and the linear transmission unit includes a rack in mesh with the gear wheel to helpfully transform the rotary kinetic energy of the driving wheel into the linear kinetic energy of the linear transmission unit.
It is a novelty for employing magnetic field effect of the solenoid to control engagement or disengagement of the driving wheel in/from the flywheel and for a transmission method of kinetic energy. Because the solenoid is received in the cylinder adjacent to the flywheel, and the two opposite end surfaces of the cylinder and the driving wheel constitute the clutch, the configuration space of the components is sufficiently saved. Moreover, the rotary kinetic energy of the flywheel is fully transmitted to the driving wheel due to the two opposite end surfaces of the driving wheel and the cylinder. In greater detail, the gear wheel is used as the driving wheel and the rack is used as the follower component of the linear transmission unit. Thus, it may be a advantageous to transform the rotary kinetic energy of the gear wheel into the linear kinetic energy of the rack, thereby improving durability of the transmission mechanism for the electrical nail gun even if the gear wheel and the rack is worn in long-termed use.
Other advantages and novel features will be drawn from the following detailed description of preferred embodiment with the attached drawings, in which:
a to
a to
a to
Referring to
The rotary transmission unit 2 includes a motor 21, a flywheel 22, a solenoid 24, and a moveable driving wheel 26.
The motor 21, which is securely mounted on bottom ends of the supporting bracket 11, 12 can be driven by the battery pack 10 controlled via the first switch 16 or the second switch 17. Alternatively, the motor 21 may be driven by other AC (Alternating Current) power supplies via a conductive wire. A drive belt wheel 210 is disposed on an axis of the motor 21.
The configuration of the flywheel 22 is similar to the configuration of the belt wheel 210. The flywheel 22 is pivotally mounted on a stop shaft 13, which is fixedly mounted between a supporting arm 14 and the supporting bracket 12 to cause the flywheel 22 to locate above the motor 21. The supporting bracket 11 outwards extends to form supporting arm 14 thereon. A belt 211 is wrapped around the drive belt wheel 210 and the flywheel 22 to cause rotation of the flywheel 22. In addition, an end side of the flywheel 22 outwards extends to form a cylinder 23, thereby rotating together with the flywheel 22. Alternatively, the cylinder 23 may be fixedly attached to the flywheel 22. The cylinder 23 should be made of magnetic materials regardless of attachment of the cylinder 23 to the flywheel 22. A ring-shaped receiving chamber 230 is defined in the cylinder 23.
The solenoid 24, which is buried in the receiving chamber 230 of the cylinder 23, does not rotate along with the flywheel 22 and the cylinder 23. In the first embodiment of the present invention, the solenoid 24 is wrapped around an insulated ring stand 240 and may be activated by current which is controlled by the first switch 16 or the second switch 17. Thus, a magnetic conductivity loop 241, as shown in
The moveable driving wheel 26, adjacent to an end side of the cylinder 23, is pivotally disposed between an engagement position 26a (shown in
In addition, the present invention also includes an elastic member 28 configured for exerting an acting force on the driving wheel 26, thereby pushing the driving wheel 26 from the engagement position 26a (shown in
Furthermore, the driving wheel 26 may be substantially a gear wheel, and the linear transmission unit 4 substantially includes a rack 41 in mesh with the gear wheel 26. A stroke bar 42 is formed on the rack 41 so that the stroke bar 42 can impact a nail when the rotary kinetic energy of the gear wheel 26 is transformed into the linear kinetic energy of the rack 41 (shown in
According to the above-mentioned configuration, two operating modes, such as a sequential actuation and a contact actuation, are performed in first embodiment of the present invention, and described in detail as follows.
Referring to
To sum up, the present invention has sufficiently taught necessary technical features which can be employed in industry. It is a novelty for employing magnetic field effect of the solenoid to control engagement or disengagement of the driving wheel in/from the flywheel and for a transmission method of kinetic energy. A reasonable configuration for the flywheel, the solenoid, the clutch, and the driving wheel causes space-saving. Furthermore, it is a advantageous to improve durability of the transmission mechanism for the electrical nail gun.
While the present invention has been illustrated by the description of preferred embodiments thereof, and while the preferred embodiments have been described in considerable detail, it is not intended to restrict or in any way limit the scope of the appended claims to such details. Additional advantages and modifications within the spirit and scope of the present invention will readily appear to those skilled in the art. Therefore, the present invention is not limited to the specific details and illustrative examples shown and described.
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