The present invention relates to flooring tools and more specifically to tools for setting hardwood plank staples.
In the installation of tongue and groove hardwood plank flooring materials, pneumatic staplers are commonly used to drive staples used to adhere the planks to the floor. These staplers are designed to sit flat on top of the hardwood plank and locate against a tongued side of the plank such that they can precisely drive the staple at a 45° angle at a point just above the tongue. The driving angle of 45° and driving elevation at the point just above the tongue are fixed and standard for most modern pneumatic hardwood staplers. The standard angle and point of entry for driving staples works well because the hardwood planks themselves normally have standard tongue and groove dimensions.
As shown in
In the use of pneumatic hardwood staplers, knots in the hardwood plank or drops in air pressure may cause the nailer to only partially drive the staple, leaving an undesirable exposed staple head.
Presently, hardwood installers normally carry snips and conventional nail sets to hammer down partially driven staples. The staple legs have to be separated from the crown, and then the legs can be driven using a conventional nail set. This is a difficult, time consuming process. If a set tool were available to drive the entire exposed staple head the rest of the way into the side of the plank, it would greatly speed the process of installation. The process of driving a partially driven staple or exposed staple head will be referred to herein as a process of “finish hammering” the hardwood staple.
Tools have been developed for hammering nails into the side of tongue and grooved flooring materials, but none for finish hammering modern hardwood staples from pneumatic staplers. For example, U.S. Pat. No. 1,016,383 to Wellman discloses a set tool with a plate which sits flat on the hardwood plank. The plate includes a “V-rib” or 90° internal angle surface formed in its base. The V-rib is shaped to conform to the plank at the exterior angle formed by the outer edge of the plank and the tongue of the plank (also referred to as a “rabbet” as this term is used in woodworking). Thus, the V-rib functions to position the plate at a precise location “to permit the effective drive of nails”. A circular “passage” for inserting a round headed nail is formed at a 45° degree angle through the plate to the vertex of the V-rib. Thus, when the point of the nail is inserted into the passage, it is automatically located at the optimal location for driving the nail at a 45° angle into the side of the plank.
In addition, the disclosed device includes a “punch or driving element” for use in connection with the plate. The punch is a generally cylindrical rod with a reduced outside diameter on one end which can slidably fit within the passage in the plate. This reduced diameter end can slide within the passage all the way to the bottom of the passage, and can thus drive the nail all the way down to the bottom of the passage. Thus, as this disclosure states, “the nail can be entirely driven into the flooring without removing the improved implement” (i.e., the “plate”).
Wellman's floor set may have worked well for the purpose of driving nails, but it is not suitable for the purpose of finish-hammering partially driven modern hardwood staples. The reason is that the passages are merely cylindrical holes designed for the passage of round headed nails. In comparison, modern hardwood staples are fairly thin, U-shaped metal wire form products. Effectively driving such staples requires that the staple be precisely supported all the way into the material by means of a precision staple channel that is shaped to create a precision slide fit with the dimensions of the staple. If a user attempted to drive such a staple with only a hammer, the lack of support means would cause the thin metal legs of the staple to bend over or break. The passage of the Wellman device will not provide the necessary precision support means for supporting the staple.
Other prior art set tools have been developed for driving staples, but they all have drawbacks. U.S. Pat. No. 1,213,334 to Chapman discloses a single-piece driving rod type staple set with a plurality of “sockets” (i.e., “blind-hole” staple channels) of varying depths formed in its driving head. The reference states that “the sockets are made of gradually decreasing depths so as to accommodate the staple at various stages of its entrance into the wood in which it is being set.” Thus, the user begins by inserting a staple in the deepest channel, and hammers on the opposite end to start the driving process. Once the driving head contacts the wood, the user inserts the staple head into one of the shallower sockets, and the staple can be driven further. The legs of the staple are supported by the various sockets, preventing them from spreading or bending over. This device is not suitable for the purpose of finish hammering hardwood staples because the plurality of sockets requires a wide head. Such a wide head does not easily enter the exterior angle formed by the outer edge of the plank and the tongue of the plank. Furthermore, modern hardwood staples are by comparison much longer and thinner than the staples shown by Chapman. More sockets of even greater depth would be necessary, and the sockets would need to be thinner. Forming enough thin blind sockets into the head would become impractical. Finally, there is no means to maintain the prescribed 45° angle during the finish hammering process. What is needed is a tool with a single staple slot with a length at least as long as the hardwood staple, and a means of driving the head of the hardwood staple down the length of the staple channel. The staple channel could be formed at the prescribed 45° angle.
Other similar set tools, such as that disclosed in U.S. Patent #D493079 S to Fowler, have more compact, relieved driving heads which include a single staple socket. Such a compact driving head can more easily enter the exterior angle formed by the outer edge of the plank, and the tongue of the plank. However, there is no means of support for the legs of the staple. This type of tool is not helpful in cases where the staple protrudes a significant distance from the hardwood plank. Without support during the driving process, the staple simply bends over.
What is needed is a set tool for finish hammering modern hardwood staples which properly supports the legs of these staples throughout the process of finish hammering while also maintaining the prescribed 45° angle and location on the plank where such staples are normally driven.
The device is a set tool including a block-like body with a staple slot formed within said body, and a separate driving rod to drive the staple. The body may sit on the face of the hardwood plank on a body base surface. The body further includes a downwardly extending arm. On its inside surface, the arm forms a stop surface for the set tool. The external angle formed by the body base surface and the stop surface is preferred to be about 75°. This angle relieves the stop surface from the outside edge of the plank (approximately 89.5° external angle in relation to the tongue), and prevents impact of the set tool at the top edge of the plank (which can cause chipping). The stop surface extends to a location where it forms a staple insertion edge with an arm base surface. The extension of the stop surface places the staple insertion edge at the vertex of the external angle formed by the outer edge of the hardwood plank, and the tongue of the plank. The arm base surface is parallel to the body base surface, and rests on top of the tongue of the plank. A staple slot is formed at the prescribed 45° angle within the body, and ending at the staple insertion edge. In use, the partially driven hardwood staple is inserted in the staple slot. The body base surface is then set on the hardwood plank. The extension and angle of the stop surface places the staple insertion edge at the vertex of the external angle formed by the outer edge of the plank, and the tongue of the plank. The user inserts the rod in the staple slot. The user slides the rod in the staple slot until it contacts the head of the staple. The user hammers the rod with a hammering tool, and the staple is driven into the hardwood plank at the prescribed angle and location. Support from the precision staple slot ensures the staple will not bend over during the process of finish hammering.
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The shape of 45° hole 230 could be any shape, including, at a minimum, a rectangular shape having a slightly greater width and thickness to permit a precise slide fit with an exposed head of a typical hardwood staple. However, a round hole is preferred so that it may be formed using a standard drill. 45° hole 230 is sized to accommodate a cylindrical rod 300 having a hammering head 305 with a thickness 302 greater than that of the thickness of a typical hardwood staple. A thicker hammering head 305 is preferred because it is easier to strike and will not bend as easily as a rod that was only the thickness of a typical hardwood staple. However, 45° hole 230 (and rod 300) are preferably not wider than the width of a typical hardwood staple. This is so a staple slot 250 can be formed by the addition of two parallel rectangular channels 255, 260. Channels 255, 260 have a precise width and thickness such that they together form a rectangular staple slot 250. The shape of staple slot 250 creates a precise slide fit to accept and support an exposed staple head during the process of finish hammering.
Channels 255, 260 have their center on the same center 240 as 45° hole 230 and are thus bisected by the same 45° bisecting plane. Channels 255, 260 are formed in 45° angle hole 230 all the way down to staple insertion edge 220. Thus, channels 255, 260 and staple slot 250 are also bisected by the line formed by staple insertion edge 220. As more clearly shown in
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As previously explained, the thickness of rod 300 is greater than the thickness of a typical hardwood staple. As shown in
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A number of alternatives may be adopted to create a plank top set tool for hardwood staples. As previously explained, it is preferred that the rod for finish hammering the staple be thicker than the thickness of the hardwood staple, in order to allow for easy hammering. However, in other alternatives, the thickness of the rod need only be about as thick as a hardwood staple. As also previously explained, for efficient manufacturing, it is preferred that the 45° angle hole be circular so that it could be machined using standard drills, and for the rod to be cylindrical. However, the 45° angle hole could be formed in a different shape, such as a triangle or square, and have a rod of corresponding shape. The use of a square or triangular 45° angle hole and corresponding rod would prevent the rod from rotating within the hole, thus eliminating the need for guide nubs and a staple slot running the full length of the 45° angle hole.
In a preferred embodiment, the rod includes a staple driving head having relieved edges forming an included angle shape, and an integral staple receiving groove formed in the relieved end. This configuration is preferred due to low manufacturing cost due to minimal parts. In another alternative, the set tool could include a staple driving head with a thin tip extension. As shown in
A thin tip such as tip 575 can have several advantages if a higher priced, more durable, and more functional set tool is desired. Rod 500 can be formed as a body 505 from a first, comparatively soft material having sufficient impact resistance for safe hammering at hammering end 507. Tip 575 may be made from a harder material which could be precision ground on the end to form a staple receiving groove 580 that conforms with the longitudinally rounded shape of the crown of the hardwood staple. Tip 575 can better drive the exposed hardwood staple head below flush into the side of hardwood plank. The lack of any exposed hardwood staple head whatsoever at the tongue and groove joint can make it easier to get the joint between planks together.
In another alternative, the rod of the set tool could incorporate a means to protect the hand from off center blows from a hammer.
In another alternative, the body of the set tool could incorporate a prying means for standing up accidentally bent over staples, or prying them out if necessary.
In another alternative, a felt pad may be added to the body base surface of the body to protect the face of the hardwood plank from being scratched.
The embodiments may be characterized in a number of different ways. For example, the device may be sold as a complete set tool, including both a body and a rod. Alternatively, the body and rod may be sold separately, requiring final assembly by a user.
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Number | Date | Country | |
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20100127037 A1 | May 2010 | US |