This invention relates broadly to explosively driven fasteners. More particularly, this invention relates to an apparatus for installing explosively driven fasteners.
For applying explosively driven fasteners to a substrate, power charges and nail lengths are all individually optimized for a given application. It would be desirable to optimize the tool to match.
It is an object of this invention to provide a spring energized tool for applying explosively driven fasteners that has a positive stop and is not springy when fully energized.
Preferred embodiments of the invention provide tools for installing an explosively driven fastener, the fastener including a nail and an explosive load attached to the nail.
The tool comprises an outer cover sleeve defining a bore, a longitudinal axis, a proximal end and a distal end. A generally tubular trigger body is fixedly positioned in the outer cover sleeve. The bore of the trigger body has a distally facing arcuate backstop face.
An end cap is positioned at the proximal end of the trigger body securing the trigger body to the outer cover sleeve.
A firing pin holder is located within the bore of the generally tubular trigger body and extends along the longitudinal axis of the trigger body. The firing pin holder has a proximal end and a distal end.
A firing spring is arranged to bias the firing pin holder distally with respect to the trigger body.
A firing pin is provided having a proximal end and a distal end. The distal end is pointed. The firing pin is separate from the firing pin holder. The proximal end of the firing pin is removably coupled to the distal end of the firing pin holder.
A nosepiece is provided having a proximal end and a distal end. The proximal end is arranged to receive a firing pin guide and the distal end is arranged to receive the fastener comprising the nail and the explosive load such that when the fastener is placed in the distal end of the nosepiece and the firing pin holder is biased out of the outer cover sleeve by the firing spring, the firing pin strikes the explosive load causing the explosive load to explode and drive the nail out of the nosepiece.
A tubular reset sleeve is provided having an inner flange facing distally and an outer flange facing proximally.
The firing pin guide is carried slidably in the reset sleeve. The firing pin guide has a distal end and a proximal end, a proximally facing outer arcuate flange abuttable against the inner flange of the reset sleeve, and an arcuate face at its proximal end abuttable against the inside distally facing arcuate backstop face in the generally tubular trigger body.
A reset spring is mounted around the firing pin guide and abuts the outer flange of the reset sleeve. The reset spring biases the reset sleeve distally.
A trigger ball and a trigger ball spring are mounted transversely in the firing pin holder. The trigger ball is biased radially outward from within the firing pin holder.
The firing pin guide has a slot extending from the proximal end and a widened area in the slot to receive the trigger ball.
When the tool is in an energized position, the trigger ball rests in the widened area of the slot thereby limiting distal movement of the firing pin, and the arcuate end face of the firing pin guide abuts or nearly abuts the arcuate backstop face in the trigger body.
For the tool to operate at its maximum potential the firing pin guide should be pushed securely against the rear of the fastener and the tip of the fastener should be pushed securely against the substrate.
The action of the operator pushing the tool forward to actuate the tool moves the trigger body forward while compressing the firing spring until the trigger body travels the exact distance needed to release the trigger ball.
A step or backstop insert is added to the inside of the trigger body. The step is designed such that at the exact distance where the trigger ball is released, the step contacts the rear of the firing pin guide. The firing pin guide cannot move backwards.
The stop allows all internal components to form a solid stack, wherein the internal elements are contacting each other, from tip of the pin assembly to the end cap.
The forward pressure of the operator actuating the tool keeps the tip of the pin assembly pressed firmly against the substrate while the firing pin impacts the load.
In the drawings, like parts in different equipment are called out by the same callout numerals.
Preferred embodiments of the invention provide tools 2, 102 for installing an explosively driven fastener 3, the fastener including a nail 4 and an explosive load 6 attached to the nail.
The tool comprises an outer cover sleeve 8, 108 defining a bore, a longitudinal axis, a proximal end and a distal end. A generally tubular trigger body 13 is fixedly positioned in the outer cover sleeve. The bore of the trigger body has a distally facing arcuate backstop face 11, 111, preferably a generally annular face.
An end cap 15, 115 is positioned at the proximal end of the trigger body securing the trigger body to the outer cover sleeve.
A firing pin holder 18 is located within the bore of the generally tubular trigger body and extends along the longitudinal axis of the trigger body. The firing pin holder has a proximal end and a distal end.
A firing spring 20 is arranged to bias the firing pin holder distally with respect to the trigger body.
A firing pin 22 is provided having a proximal end and a distal end. The distal end is pointed. The firing pin is separate from the firing pin holder. The proximal end of the firing pin is removably coupled to the distal end of the firing pin holder.
A nosepiece 24, 124 is provided having a proximal end and a distal end. The proximal end is arranged to receive a firing pin guide 32 and the distal end is arranged to receive the fastener comprising the nail and the explosive load such that when the fastener is placed in the distal end of the nosepiece and the firing pin holder is biased out of the outer cover sleeve by the firing spring, the firing pin strikes the explosive load causing the explosive load to explode and drive the nail out of the nosepiece.
A tubular reset sleeve 26 is provided having an inner flange 28 facing distally and an outer flange 30 facing proximally.
The firing pin guide is carried slidably in the reset sleeve. The firing pin guide has a distal end and a proximal end, a proximally facing outer annular flange 34 abuttable against the inner flange of the reset sleeve, and an annular face at its proximal end abuttable against the inside distally facing arcuate backstop face in the generally tubular trigger body.
A reset spring 36 is mounted around the firing pin guide and abuts the outer flange of the reset sleeve. The reset spring biases the reset sleeve distally.
A trigger ball 38 and a trigger ball spring 40 are mounted transversely in the firing pin holder. The trigger ball is biased radially outward from within the firing pin holder.
The firing pin guide has a slot 50 extending from the proximal end and a widened area 52 in the slot to receive the trigger ball.
When the tool is in an energized position, the trigger ball rests in the widened area of the slot thereby limiting distal movement of the firing pin, and the arcuate preferably annular end face of the firing pin guide abuts or nearly abuts the arcuate preferably annular backstop face in the trigger body.
In one embodiment of the invention, (
In one embodiment of the invention, a grip 10 extends transversely from the outer cover sleeve between the proximal end and the distal end. A trigger 12 is pivotally connected to the outer cover sleeve and biased distally away from the grip by a trigger spring 14 positioned between the grip and the trigger. The trigger has an upper surface and a nose 16 protruding from its upper surface toward the longitudinal axis of the outer cover sleeve. The nose enters the bore of the outer cover sleeve when the trigger is depressed toward the grip. The generally tubular trigger body defines a longitudinally extending slot 70 which receives the nose of the trigger when the trigger is depressed toward the grip. When the tool is in a firing position, the trigger nose depresses the trigger ball out of engagement with the firing pin guide to allow distal movement of the firing pin under the action of the firing spring.
In one embodiment of the invention, the distally facing arcuate backstop face of the generally tubular trigger body comprises an annular step in the bore of the trigger body and is unitary with the trigger body.
One embodiment of the invention further comprises a blocking element 41 carried for radial movement by generally tubular trigger body to selectively block proximal movement of the firing pin guide and prevent energization of the firing pin spring. A cam 42 is mounted across the outer cover sleeve, and an arm is positioned on one end of the cam to permit about a 90 degree rotation of the cam to selectively block radially outward movement of the blocking element and prevent the firing pin guide from moving sufficiently proximally for the firing pin spring to be energized. The safety is preferably a ball bearing that contacts the distal end of the firing pin holder.
In one embodiment of the invention, a tubular debris cup 72 is attached to the nosepiece in a covering coaxial relationship. A threaded reset sleeve cap 76 is positioned on the distal end of the reset sleeve and retains the proximal end of the nosepiece against the distal end of the reset sleeve. A nosepiece spring 74 is positioned between the debris cup and the reset sleeve cap annularly to the nosepiece urging the debris cup distally from the reset sleeve cap and extending the nosepiece to its full distal position. The tubular debris cup rides over the reset sleeve cap and the reset sleeve when the nosepiece spring is compressed. The outer cover sleeve rides over the reset sleeve when the reset sleeve spring is compressed. Compression of the nosepiece spring and the reset sleeve spring brings the distal end of the firing pin guide to a position adjacent the distal end of the nosepiece. See
These features enable the tool to accept fastener assemblies from 1″ to 2½″ and be able to eject debris or an unfired fastener assembly and reset the tool properly. The nosepiece is no longer screwed into the reset sleeve. Instead, the nosepiece can travel freely on the firing pin guide and is connected to the reset sleeve by a new reset sleeve cap. The fastener assembly is inserted into the nosepiece. Then the operator will lightly compress the tool until the tip of the nail pushes against the substrate. The tip of the firing pin guide pushes against the charge holding the nail in place. A spring (added between the lip of the firing pin guide and the nosepiece, or between the extended debris cup and the reset spring cap) pushes the nosepiece to full extension. The modified nosepiece can travel into the body of the reset sleeve. During ejection, the nosepiece is first pushed into the reset sleeve reducing the total space inside the nosepiece to less than 40 mm, then the firing pin guide advances 40 mm fully ejecting any plastic or debris stuck inside the nosepiece.
For cocking, the firing pin is carried proximally with proximal movement of the firing pin guide to compress the firing pin spring until the firing pin is released from the firing pin guide.
In some embodiments, a spall shield 80 is mounted to the distal end of the nosepiece to provide greater worker safety for nail sets in concrete.