An electric carpet stapler is an electrically-powered tool for stapling carpet to wooden subfloor surfaces to prevent the carpet from moving, particularly on staircases. U.S. Pat. No. 3,209,180 to Doyle describes a prior art electric carpet stapler which includes an operating winding, an armature attached to a fastener driving element, an armature return spring, a switch, and a control circuit. In various ways, a switch like Doyle's may be used to produce a trigger signal to a control circuit, or to temporarily provide mains power to a control circuit. After being triggered, the control circuit begins a process that supplies power to the operating winding to magnetically actuate the armature. Examples of prior art control circuits are described in U.S. Pat. No. 3,141,171 to Doyle, U.S. Pat. No. 3,434,026 to Doyle, U.S. Pat. No. 3,662,190 to Naber, and U.S. Pat. No. 3,924,789 to Avery.
In the device of U.S. Pat. No. 3,209,180 to Doyle, as shown in
To produce a trigger signal for a control circuit, trigger 80 is pulled, which through a series of actions results in switch operator 38a of switch 38 being depressed. Switch 38 is generally a “snap action” microswitch, which is mechanical and quite small in size, and which can fit in the handle 12 along with the control circuit (not shown). However, as shown in
Existing control circuits for an electric carpet stapler have generally depended on a mechanical microswitch that is separate from the control circuit element itself to cause the control circuit to supply power to the winding. In one design, when mains power is connected, power is supplied to the control circuit. The microswitch, which is wired to the control circuit, switches a lower voltage signal, which when in the closed condition signals the control circuit to begin a process to supply power to the winding. Since the electric carpet stapler is designed to operate on alternating current electricity available in homes, the control circuit is generally programmed to delay sending a control signal to a gate or SCR (“silicon-controlled rectifier”) until a zero crossing of the alternating current, at which time it supplies power to the winding.
To further describe the functions of the trigger assembly of a prior art electric carpet stapler, it generally has included a pivoting trigger, a trigger return spring, and the prior art microswitch. When the trigger is first pulled by a user, to prevent unwanted actuation, the trigger will pivot from a starting position and bias a trigger return spring before causing the microswitch to close, a process that will be referred to as “pre-actuation.” After the pre-actuation, the “actuation” occurs as the microswitch closes, which creates a signal to the control circuit to begin a process to supply power to the winding. At or just after the actuation, the assembly may mechanically produce a palpable signal to the user or “click” that indicates the point in the trigger's motion that corresponds to the actuation. The click signal is often produced by the mechanical microswitch at about the time it closes. This can be helpful for training the user to use the electric carpet stapler, when the stapler is preferably not connected to power. After the actuation, a “post actuation” permits further travel of the trigger in the pulling direction, conforming to the natural motion of the trigger finger, and eliminating an unergonomic hard stop. At any point after the trigger is first pulled by a user, a “reset” of the assembly involves the return of the trigger to its starting position, normally by the trigger return spring, and the opening of the microswitch.
Beyond producing the actuation, the design of the trigger assembly should ensure that, for any one pulling of the trigger, at most one actuation can possibly occur. In existing trigger assemblies, this is partly ensured by the single acting “over center” closing action of microswitch. It is also ensured by the action of the trigger return spring, which ensures that the trigger once released will only rotate back to the trigger starting position, preventing the microswitch from closing again on its own.
To reduce maintenance costs for the prior art electric carpet stapler related to the microswitch, it would be desirable to provide a more durable trigger and switch assembly, which could still perform the functions of the prior art trigger assembly, microswitch, and control circuit.
Embodiments of the invention include an electric carpet stapler that comprises a trigger and switch assembly that has an actuation caused by a change of state of a sensor, which causes the sensor to send a signal to a control circuit to begin a process to supply power to a winding. In one embodiment, the trigger and switch assembly includes a trigger that moves in a trigger actuation direction to move a sensor actuator in a sensor actuation direction, causing a change of state in the sensor comprising a change from a sensor signal-on state to a sensor signal-off state, which causes the control circuit to begin the process to supply power to the winding. In another embodiment, the change of state of the sensor comprises a change from a sensor-signal-off state to a sensor signal-on state, which causes the control circuit to begin the process to supply power to the winding.
In one embodiment, the trigger and switch assembly includes a trigger that moves a sensor actuator comprising a slider, a sensor comprising a photo sensor, and the control circuit. The photo sensor includes a light emitter comprising a light emitting diode that emits infrared light and a light sensor that comprises a silicon photo transistor. As the trigger is pulled, it moves the slider to permit or prevent the infrared light from passing to the silicon photo transistor. In one embodiment of the control circuit, when light contacts the silicon photo transistor, the silicon photo transistor behaves as a switch that closes to conduct to ground. This causes the voltage on a conductor to the control circuit to drop to near-zero, which is referred to herein as a sensor signal-off signal. When the control circuit detects the sensor signal-off signal, it begins the process to supply power to the winding. Afterwards, when the trigger is released, the slider prevents light from contacting the silicon photo transistor. This causes the photo sensor to behave like a switch that opens to cause a sensor sensor-on signal, which increases the voltage on the conductor to the control circuit and thereby resets the control circuit to receive a next sensor signal-off signal.
In an alternative embodiment of the control circuit, when the slider permits light to pass to the silicon photo transistor, the silicon photo transistor conducts creating a signal on the conductor to the control circuit comprising an increase in voltage to signal the control circuit to begin a process to supply power to the winding.
In one embodiment, the trigger and switch assembly includes a trigger that moves from a trigger starting position in a trigger actuation direction to move a sensor actuator comprising a slider, and a sensor comprising a photo sensor that senses the passing of light from a light emitter to a light sensor. In one embodiment, the slider includes a slider aperture, and the motion of the trigger in the trigger actuation direction moves the slider in a slider actuation direction moving the slider aperture to permit light to pass from the light emitter of the photo sensor to the light sensor, causing a change of state of the photo sensor, from a sensor signal-on state to a sensor signal-off state, which signals the control circuit to begin the process to supply power to the winding. The point at which the trigger has moved far enough in the trigger actuation direction to move the slider aperture far enough to permit light to pass from the light emitter of the photo sensor to the light sensor is referred to as the trigger point of actuation. The point at which the trigger is stopped from moving any further in the trigger actuation direction at the end of the post-actuation is referred to as the trigger stop. In one embodiment, the slider aperture has a length permitting light to pass from the light emitter of the photo sensor to the light sensor in the entire travel of the slider as it is moved by the trigger from the trigger point of actuation to the trigger stop.
In another embodiment, the trigger and switch assembly includes a trigger, a photo sensor, and a sensor actuator comprising a slider, and the trigger instead moves the slider to prevent light from passing from the light emitter of the photo sensor to the light sensor, causing the change of state of the photo sensor which signals the control circuit to begin a process to supply power to a winding.
In another embodiment, the trigger and switch assembly comprises a trigger that moves a slider, and the slider moves in a horizontal axis of the handle portion of the electric carpet stapler. In another embodiment, the photo sensor includes an opening for the slider in the horizontal axis of the handle. In another embodiment, the photo sensor is positioned in a portion of the control circuit proximate the trigger.
In another embodiment, the trigger and switch assembly includes a trigger that moves a sensor actuator, a sensor, and a toggle. At the actuation of the trigger and switch assembly, the toggle creates a mechanical instability, requiring the trigger to move either towards the trigger stop, or towards the trigger starting position, but will not allow it to remain at the trigger point of actuation. In one embodiment, at the actuation, the change of state in the sensor caused by the sensor actuator happens at the same point that the mechanical instability occurs in the trigger and switch assembly. In one embodiment, at or shortly after the actuation, the toggle creates a toggle signal to the user. In one embodiment, the toggle signal is produced mechanically.
In one embodiment, the trigger and switch assembly includes a trigger, a sensor actuator comprising a slider, a photo sensor, and a toggle comprising a point on the slider that contacts another point on the trigger and switch assembly. In one embodiment, the toggle comprises a rounded projection on the slider which comes into contact with an apex of a circular ball, and a ball spring that is biased as the ball is moved. A pulling motion of the trigger by a user from the trigger starting position produces motion of the slider in a pulling direction, causing the rounded projection of the slider to contact the ball, which lifts the ball up a leading section of the rounded projection, and which biases the ball spring. At the actuation, an unstable point-to-point contact between the apex of the rounded projection of the slider and the apex of the ball produces the mechanical instability. In one embodiment, at the actuation, the mechanical instability between the rounded projection of the slider and the ball occur at the same time that the slider changes the state of the sensor to cause the control circuit to begin a process to supply power to a winding.
In one embodiment, the trigger and switch assembly comprises a trigger that moves a slider having a slider aperture, a trigger return spring, a photo sensor, a control circuit, and a toggle comprising a rounded projection on the slider, a ball, and a ball spring. When the trigger is pulled and moves from the trigger starting position, the trigger return spring is biased to return the trigger to a trigger starting position. After the trigger is pulled in a trigger actuation direction far enough to move the slider aperture to permit light to pass from the light emitter of the photo sensor to the light sensor to cause the control circuit to begin a process to supply power to the winding, the apex of the rounded projection of the slider is in an unstable point-to-point contact with the apex of the ball and produces the mechanical instability. At this mechanical instability, the trigger is required to move either by being further pulled in the trigger actuation direction by a user towards the trigger stop, and in such case the slider aperture has a length permitting light to continue to pass as it is pulled by the trigger to the trigger stop, or else the trigger if released is required to return to the trigger starting position due the bias of the return spring, which moves the slider aperture to prevent light from passing from the light emitter of the photo sensor to the light sensor. When light is prevented from passing to the light sensor, this causes a change of state of a photo sensor which resets the control circuit for the next process to supply power to the winding. In the pre-actuation, whether the trigger is pulled or released, there will also be no change in state of the photo sensor, because the slider will not have moved enough to permit light to pass. For these reasons, any pulling of the trigger by a user should cause the control circuit to begin a process to supply power to winding one time only.
In one embodiment, instantaneously after the actuation, continued pulling motion of the trigger pulls the slider which permits the ball to move down a steep trailing section of the rounded projection, causing the ball to be accelerated by the ball spring to impact a surface, creating a toggle signal comprising a click that is produced mechanically. In one embodiment, when the electric carpet stapler is not connected to power, if the trigger is pulled, the mechanical click is an indication to a user that the actuation would occur at about the time of the click.
In one embodiment of the trigger and switch assembly, after the trigger is pulled from a trigger starting position, to any point in the pre-actuation, actuation, or post-actuation, a subsequent reverse motion of the trigger in a trigger reset direction is referred to as a reset. In one embodiment, if in the reset the trigger moves from the actuation or post-actuation to the pre-actuation, the trigger moves the sensor actuator to cause another change of state in the sensor comprising a change from a sensor signal-off state to a sensor signal-on state, and the sensor signal-on state sends a signal to the control circuit that resets it to receive a next sensor signal-off signal to supply power to the winding. In another embodiment, the change of state of the sensor is from a sensor signal-on state to a sensor signal-off state, which resets the control circuit to receive a next signal-on signal to supply power to the winding.
In one embodiment, during a reset after an actuation, the trigger is moved in a trigger reset direction towards a trigger starting position. This causes a slider having a slider aperture to move in a slider reset direction and thereby prevents light from passing from the light emitter of the photo sensor to the light sensor. This also causes another change of state of a photo sensor comprising a sensor signal-on state, resetting the control circuit to receive a next sensor signal-off signal to supply power to the winding. In another embodiment, the slider moves in the slider reset direction to permit light to pass from the light emitter of the photo sensor to the light sensor, causing the change of state of the photo sensor to reset the control circuit to receive a next signal to supply power to the winding.
In one embodiment, the trigger and switch assembly further includes a trigger return spring that is biased after the trigger is pulled to return the trigger in the trigger reset direction to a trigger starting position of the pre-actuation. In one embodiment, at the starting position of the pre-actuation, the rounded projection of the slider no longer contacts the ball.
The figures depict various embodiments of the present invention for purposes of illustration only. One skilled in the art will readily recognize from the following discussion that alternative embodiments of the structures and methods illustrated herein may be employed without departing from the principles of the invention described herein.
As shown in Section A-A of
Section G-G of
Referring back to
In the beginning of the pre-actuation, as shown in Section B-B, ball 10900 is not in contact with rounded projection 10320, but rests against an outer forward surface 10332 of metal sleeve 10330. During the pre-actuation, as trigger 10100 (
After the actuation, Section E-E of
In the post-actuation, as shown in Section E-E, because of the length 10351 (Section F-F) of aperture 10350, light continues being permitted to pass from the light emitter 10411 of to the light sensor 10412 of photo sensor 10410, causing no change of state of photo sensor 10410. As a result, during the post-actuation, photo sensor 10410 cannot have a change of state or send a second signal to the control circuit 10400 to begin a process to supply power to the winding 10700 (Section E-E) a second time.
As shown in Section E-E of
At the actuation, as shown in Section C-C of
As shown in Section E-E of
As shown in Section G-G of
Afterwards, when the trigger is released the slider prevents light 10414 from light emitter 10411 from contacting light sensor 10412. This causes light sensor 10412 to behave like a switch that opens to cause a signal referred to herein as a sensor signal-on signal, comprising an increase in voltage on the conductor 10457 to the logic circuit 10460. This resets the logic circuit 10460 to receive a next sensor signal-off signal.
In one embodiment, logic circuit 10460 is a microchip programmed to sense changes in voltage on conductor 10457 and can supply a current on the gate 10461 to control a silicon-controlled rectifier 10462 to supply power to winding 10700. In alternative embodiments to the photo sensor circuit 10450, the light sensor 10412 conducts an alternative type of signal to the conductor to the control circuit, for example an increase in voltage that signals the logic circuit 10460 to begin a process to supply power to the winding.
Embodiments of the invention described herein employ an electronic sensor comprising a photo sensor that has a change of state in response to the motion of a sensor actuator. Other embodiments use other types of electronic sensors, including inductive sensors that create magnetic fields that when disturbed change the state of the sensor, or capacitive sensors that sense changes in capacitance. However, photo sensors advantageously provide low cost and very durable designs that can withstand vibration and that are also not affected by electrical interference produced by the winding.
As used herein, and as shown in
The foregoing description of the embodiments of the invention has been presented for the purpose of illustration; it is not intended to be exhaustive or to limit the invention to the precise forms disclosed. Persons skilled in the relevant art can appreciate that many modifications and variations are possible in light of the above disclosure. The language used in the specification has been principally selected for readability and instructional purposes, and it may not have been selected to delineate or circumscribe the inventive subject matter. It is therefore intended that the scope of the invention be limited not by this detailed description, but rather by any claims that issue on an application based hereon. Accordingly, the disclosure of the embodiments of the invention is intended to be illustrative, but not limiting, of the scope of the invention, which is set forth in the following claims.