Cross-reference is made to U.S. Utility patent application Ser. No. 12/191,935 entitled “Cordless Nail Gun” by Krondorfer et al., which was filed on Aug. 14, 2008; to U.S. Utility patent application Ser. No. 12/191,948 entitled “Cordless Nailer With Safety Sensor” by Krondorfer et al., which was filed on Aug. 14, 2008; to U.S. Utility patent application Ser. No. 12/191,960 entitled “Cordless Nailer With Safety Mechanism” by Krondorfer et al., which was filed on Aug. 14, 2008; and to U.S. Utility patent application Ser. No. 12/191,979 entitled “Cordless Nailer Drive Mechanism Sensor” by Hlinka et al., which was filed on Aug. 14, 2008, the entirety of each of which is incorporated herein by reference.
This invention relates to the field of devices used to drive fasteners into work-pieces and particularly to a device for impacting fasteners into work-pieces.
Fasteners such as nails and staples are commonly used in projects ranging from crafts to building construction. While manually driving such fasteners into a work-piece is effective, a user may quickly become fatigued when involved in projects requiring a large number of fasteners and/or large fasteners. Moreover, proper driving of larger fasteners into a work-piece frequently requires more than a single impact from a manual tool.
In response to the shortcomings of manual driving tools, power-assisted devices for driving fasteners into wood have been developed. Contractors and homeowners commonly use such devices for driving fasteners ranging from brad nails used in small projects to common nails which are used in framing and other construction projects. Compressed air has been traditionally used to provide power for the power-assisted devices. Specifically, a source of compressed air is used to actuate a cylinder which impacts a nail into the work-piece. Such systems, however, require an air compressor, increasing the cost of the system and limiting the portability of the system. Additionally, the air-lines used to connect a device to the air compressor hinder movement and can be quite cumbersome and dangerous in applications such as roofing.
Fuel cells have also been developed for use as a source of power for power-assisted devices. The fuel cell is generally provided in the form of a cylinder which is removably attached to the device. In operation, fuel from the cylinder is mixed with air and ignited. The subsequent expansion of gases is used to push the cylinder and thus impact a fastener into a work-piece. These systems are relatively complicated as both electrical systems and fuel systems are required to produce the expansion of gases. Additionally, the fuel cartridges are typically single use cartridges.
Another source of power that has been used in power assisted devices is electrical power. Traditionally, electrical devices have been mostly limited to use in impacting smaller fasteners such as staples, tacks and brad nails. In these devices, a solenoid driven by electrical power from an external source is used to impact the fastener. The force that can be achieved using a solenoid, however, is limited by the physical structure of the solenoid. Specifically, the number of ampere-turns in a solenoid governs the force that can be generated by the solenoid. As the number of turns increases, however, the resistance of the coil increases necessitating a larger operational voltage. Additionally, the force in a solenoid varies in relation to the distance of the solenoid core from the center of the windings. This limits most solenoid driven devices to short stroke and small force applications such as staplers or brad nailers.
Various approaches have been used to address the limitations of electrical devices. In some systems, multiple impacts are used. This approach requires the tool to be maintained in position for a relatively long time to drive a fastener. Another approach is the use of a spring to store energy. In this approach, the spring is cocked (or activated) through an electric motor and gearbox. Once sufficient energy is stored within the spring, the energy is released from the spring into an anvil which then impacts the fastener into the substrate. The force delivery characteristics of a spring, however, are not well suited for driving fasteners. As a fastener is driven further into a work-piece, more force is needed. In contrast, as a spring approaches an unloaded condition, less force is delivered to the anvil.
Flywheels have also been used to store energy for use in impacting a fastener. The flywheels are used to launch a hammering anvil that impacts the nail. A shortcoming of such designs is the manner in which the flywheel is coupled to the driving anvil. Some designs incorporate the use of a friction clutching mechanism that is both complicated, heavy and subject to wear. Other designs use a continuously rotating flywheel coupled to a toggle link mechanism to drive a fastener. Such designs are limited by large size, heavy weight, additional complexity, and unreliability.
Power-assisted impacting tools incorporate a motor to provide the energy which is used to impact a fastener. The motor is typically a motor which incorporates brushes. Brushed motors are effective for generating a rotational torque from a direct current power source. Brushed motors, however, occupy a large amount of space, resulting in a bulky tool. Moreover, the brushed motors are relatively heavy and inefficient. Additionally, brushed motors generate sparks which are not desired in dusty environments and the brushed motors are relatively inefficient. Lastly, a brushed motor requires a speed reducing mechanism (i.e. belt or gearbox) that couples the armature shaft to the flywheel in order to provide the necessary torque to accelerate the flywheel.
What is needed is an energy storage system which can be used to control delivery of impacting force in a device which is reliable and safe and does not increase the number of mechanical switches. What is needed is a system which can be used to provide impacting force in a device using low voltage energy sources. What is further needed is a system which is reliable and does not require a continuously rotating flywheel. A further need exists for a device which exhibits improved efficiency, and which is lighter, or smaller, or quieter than a tool incorporating a brushed motor.
In accordance with one embodiment, there is provided a device for impacting a fastener which includes a drive mechanism configured to impact a fastener, a lever arm pivotable between a first position and a second position, and a motor including a plurality of permanent magnets mounted on a rotatable housing, the motor mounted on the lever arm such that when the lever arm is in the first position, the rotatable motor housing is isolated from the drive mechanism and when the lever arm is in the second position, the rotatable motor housing is positioned to transfer rotational energy to the drive mechanism.
In accordance with another embodiment, a method of impacting a fastener includes energizing a motor including a plurality of permanent magnets, rotating a housing using the plurality of permanent magnets, engaging the rotating housing and a drive mechanism, and transferring energy from the rotating housing to the drive mechanism.
In accordance with a further embodiment, a device for impacting a fastener includes a frame, a lever arm pivotably mounted to the frame, an outrunner motor mounted to the lever arm, a drive mechanism for impacting a fastener, and a solenoid configured to pivot the lever arm between a first position wherein rotational energy from the outrunner motor is isolated from the drive mechanism and a second position wherein rotational energy from the outrunner motor can transfer to the drive mechanism.
For the purposes of promoting an understanding of the principles of the invention, reference will now be made to the embodiments illustrated in the drawings and described in the following written specification. It is understood that no limitation to the scope of the invention is thereby intended. It is further understood that the present invention includes any alterations and modifications to the illustrated embodiments and includes further applications of the principles of the invention as would normally occur to one skilled in the art to which this invention pertains.
The motor 114 is mounted on a lever arm assembly 126 as shown in
The motor 114 is supported by the motor bracket 132. The motor 114 in one embodiment is an outrunner motor. Thus, as shown in
Continuing with
Referring to
The spring loaded switch 210 is used to provide input to a control circuit 220 shown in
A schematic diagram of the motor circuit 224 is shown in
The motor circuit 224 includes an FET driver portion 248. The driver portion 248 is connected through NMOS FETs 250, 252, 254, 256, 258, and 260 to the motor 114. A capacitor 262 is connected to the drains of the high side NMOS transistors 250, 254, and 258.
Rotation of the motor 114 is accomplished by activating the trigger 206 to apply power to the power input 246. The application of power further completes a circuit allowing current to flow through a sensor resistor 264.
More specifically, the NMOS FETs 250 and 256 are controlled as a pair by the driver portion 248 to produce a single phase of power to the motor 114. When a signal is presented to the gate 268 of the NMOS FET 250, the NMOS FET 250 couples the motor terminal 270 to battery power. When a signal is presented to the gate 272 of NMOS FET 256, the NMOS FET 256 couples the motor terminal 274 to ground, allowing current to flow and causing the motor to rotate.
Similarly, the NMOS FETs 254 and 260 are controlled as a pair to provide a second phase of power to the terminal 274 of the motor 114 and the NMOS FETs 258 and 252 are controlled as a pair to provide a third phase of power to the terminal 276 of the motor 114. Thus, the NMOS FETs 250, 252, 254, 256, 258, and 260 are configured as a three pair half bridge, which are controlled by the motor circuit 224 to provide three phase power to the motor 114.
When rotation of the motor 114 is no longer desired, the trigger 206 may be released, thereby removing power from the motor circuit 224.
Further detail and operation of the fastener impacting device 100 is described with initial reference to
As the pivot arm 196 pivots about the pivot pin 200, the hook portion 202 of the pivot arm 196 rotates out of the stop slot 204. This allows the trigger 206 to be moved toward the spring loaded switch 210 shown in
The rotation of the drive wheel 160 is sensed by the drive wheel speed sensor 230 and a signal indicative of the rotational speed of the drive wheel 160 is passed to the processor 222. The processor 222 controls the motor 114 to increase the rotational speed of the drive wheel 160 until the signal from the drive wheel speed sensor 230 indicates that a sufficient amount of kinetic energy has been stored in the drive wheel 160.
In response to achieving a sufficient amount of kinetic energy, the processor 222 causes the supply of energy to the motor 114 to be interrupted, allowing the motor 114 to be freely rotated by energy stored in the rotating drive wheel 160. The processor 222 further starts the timer 232 and controls the solenoid circuit 228 to power the solenoid 124 whereby a pin 296 is forced outwardly from the solenoid 124 in the direction of the arrow 298 shown in
The pin 296 thus forces the springs 138 and 140 to be compressed within the spring wells 134 and 136. As the springs 138 and 140 are compressed by the expulsion of the pin 296, the lever arm assembly 126 rotates about the pivot pin 130 in the direction of the arrow 298 of
Rotation of the lever arm 126 forces the grooves 162 of the drive wheel 160 into complimentary grooves 300 of the drive member 170 shown in
If desired, the motor and drive wheel may be mounted to the device housing rather than mounted on a pivot arm. In such embodiments, rotational energy from the motor housing may be transferred by movement of a drive mechanism into contact with the motor housing, such as by mounting the drive mechanism on a pivoting arm.
Continuing with the example, movement of the drive member 170 along the drive path moves the anvil 172 into the drive channel 186 through the central bore 184 of the front bumper 178 so as to impact a fastener located adjacent to the drive section 110.
Movement of the drive member 170 continues until either a full stroke has been completed or until the timer 232 has timed out. Specifically, when a full stroke is completed, the permanent magnet 176 is located adjacent to the Hall Effect sensor 188 (see
In alternative embodiments, the Hall Effect sensor may be replaced with a different sensor. By way of example, an optical sensor, an inductive/proximity sensor, a limit switch sensor, or a pressure sensor may be used to provide a signal to the processor 222 that the drive member 170 has reached a full stroke. Depending upon various considerations, the location of the sensor may be modified. For example, a pressure switch may be incorporated into the front bumper 178. Likewise, the component of the drive member 170 which is sensed, such as the magnet 176, may be positioned at various locations on the drive member 170. Additionally, the sensor may be configured to sense different components of the drive member 170 such as the flange 174 or the anvil 172.
De-energization of the solenoid 124 allows the pin 296 to move back within the solenoid 124 as the energy stored within the springs 138 and 140 causes the springs 138 and 140 to expand thereby rotating the lever arm 126 in the direction opposite to the direction of the arrow 298 (see
The solenoid 124 and lever arm 126 are thus returned to the condition shown in
Returning to the embodiment of
In alternative embodiments, the processor 222 can accept a trigger input associated with the trigger 206 and a WCE input associated with the WCE 194. The trigger input and the WCE input may be provided by switches, sensors, or a combination of switches and sensors. In one embodiment, the WCE 194 no longer needs to interact with the trigger 206 via an actuating mechanism 190 including a pivot arm 196 and a hook portion 202. Rather, the WCE 194 interacts with a switch (not shown) that sends a signal to the processor 222 that indicates when the WCE 194 has been depressed. The WCE 194 may also be configured to be sensed rather than to be engaged with a switch. The sensor (not shown) may be an optical sensor, an inductive/proximity sensor, a limit switch sensor, or a pressure sensor.
In this alternative embodiment, the trigger switch can include a sensor that detects the position of the trigger. This alternative embodiment can operate in two different firing modes, which is user selectable by a mode selection switch (not shown). In a sequential operating mode, depression of the WCE 194 causes a WCE signal, based upon a switch or a sensor, to be generated. In response, the processor 222 executes program instructions causing battery power to be provided to the motor 114. The processor 222 may also energize the sensor 210 based upon the WCE signal. When the drive wheel speed sensor 230 indicates a desired amount of kinetic energy has been stored in the drive wheel 160, the processor 222 then controls the motor 114 to maintain the rotational speed of the drive wheel 160 that corresponds to the kinetic energy desired.
If desired, an operator may be alerted to the status of the kinetic energy available. By way of example, the processor 222 may cause a red light (not shown) to be energized when the rotational speed of the drive wheel 160 is lower than the desired speed and the processor 222 may cause a green light (not shown) to be energized when the rotational speed of the drive wheel 160 is at or above the desired speed.
In addition to causing energy to be provided to the motor 114 upon depression of the WCE 194, the processor 222 starts a timer when battery power is applied to the motor 114. If a trigger signal is not detected before the timer times out, battery power will be removed from the motor 114 and the sequence must be restarted. The timer 232 may be used to provide a timing signal. Alternatively, a separate timer may be provided.
If the trigger 206 is manipulated, however, the processor 222 receives a trigger signal from the trigger switch 210 or a trigger sensor. The processor 222 then causes the supply of energy to the motor 114 to be interrupted, as long as the kinetic energy in the drive wheel 160 is sufficient, allowing the motor 114 to be freely rotated by energy stored in the rotating drive wheel 160. The processor 222 further starts the first timer 232 and controls the solenoid circuit 228 to power the solenoid 124. In response to the first of a signal from the driver block sensor 188 or timing out of the timer 232, the processor 212 is programmed to interrupt power to the solenoid circuit Both the WCE switch/sensor and the trigger switch or trigger sensor 206 must be reset before another cycle can be completed.
Alternatively, an operator may select a bump operating mode using a mode selection switch. In embodiments incorporating a trigger sensor, positioning of the selection switch in the bump mode setting causes the trigger sensor to be energized. In this mode of operation, the processor 222 will supply battery power to the motor 114 in response to either the WCE switch/sensor signal or the trigger switch/sensor signal. Upon receipt of the remaining input signal, the processor 222 verifies that the desired kinetic energy is stored in the drive wheel 160 and then causes the supply of power to the motor 114 to be interrupted and the battery power is supplied to the solenoid 124. In response to the first of a signal from the driver block sensor 188 or timing out of the timer 232, the processor 222 is programmed to interrupt power to the solenoid circuit 228.
In another embodiment, continued depression of the trigger 206 causes the motor 114 to be energized. Activation of the solenoid 124, however, is not allowed until the WCE 194 has been released and then pressed against a work piece. In this embodiment, called bump-mode, a sensor may be used to signal the condition of the WCE.
In bump operating mode, only one of the two inputs must be reset. The processor 222 will supply battery power to the motor 114 immediately after the solenoid power is removed as long as at least one of the inputs remains activated when the other input is reset. When the reset input again provides a signal to the processor 222, the sequence described above is once again initiated.
While the invention has been illustrated and described in detail in the drawings and foregoing description, the same should be considered as illustrative and not restrictive in character. It is understood that only the preferred embodiments have been presented and that all changes, modifications and further applications that come within the spirit of the invention are desired to be protected.
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Number | Date | Country | |
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20100213232 A1 | Aug 2010 | US |