NZ500767A - Making a steel pin for axial, non-rotational penetration of a steel, concrete or masonry substrate - Google Patents

Abstract

Described is a method of making a steel pin. The method comprises: (i) forming a predetermined length of carbon steel wire into two parts, a head and a shank. (ii) Rolling the shank end to a point to form the pin and (iii) Heating the steel to harden it.

Description

t» 767 Under the provisions of Regulation 23 the Specification has been ante-dated to 19?.<£ Initials Patents Form No. 5 OurRef: JI212393 This is a divisional out of application number 333349 dated 14 December 1998.

NEW ZEALAND PATENTS ACT 1953 COMPLETE SPECIFICATION PIN-MAKING METHOD We, ILLINOIS TOOL WORKS, INC., a body corporate under the laws of Delaware, USA of 3600 West Lake Avenue, Glenview, Cook County, Illinois 60025, United States Of America, United States Of America hereby declare the invention, for which We pray that a patent may be granted to us and the method by which it is to be performed, to be particularly described in and by the following statement: PT0585036 INTELLECTUAL PROPERTY QFFIC'T OF N.Z. 29 OCT 1999 t RECEIVED PIN-MAKING METHOD TECHNICAL FIELD OF THE INVENTION This invention pertains to a method of making a pin.

BACKGROUND OF THE INVENTION As exemplified in Almeras et al. U.S. Patent No. 4,824,003, which issued to Societe de Prospection et d'Inventions Techniques S.P.I.T. of Paris, France, it is known to provide a steel pin having a head, a shank, and a point with a steel washer having an outer diameter equal approximately to the outer diameter of the head, for guiding the steel pin in the muzzle, barrel, or nosepiece of a driving or setting tool. The steel washer is carried on the shank, in axially spaced relation to the head, and is movable toward the head when the pin with the washer is driven forcibly into a substrate, either directly or through a workpiece, so that the washer bears against the substrate or the workpiece. As exemplified therein, the steel washer also performs an energy-absorbing function.

As exemplified by a steel pin made and sold by Societe de Prospection et d'Inventions Techniques S.P.I.T., supra, under Product Designation SBR 14, it is known for the steel pin to have a head, an ogival point, a knurled shank, which is not tapered, and a transition zone having a tapered portion between the knurled shank and the head. The SBR 14 pin is made from carbon steel having a carbon content in a range from 0.58 percent to 0.62 percent.

As known heretofore, the steel pin can be made from a predetermined length of carbon steel wire, which has a carbon content not less than 0.35 percent and which can be surface hardened or through hardened. AISIC 1038 steel, which has a carbon content in a range from 0.35 percent to 0.41 percent, can be thus used. Moreover, the predetermined length of carbon steel wire is formed in an (followed by page 2) initial step so as to form an intermediate part, which has a head to become the head of the steel pin, a shank to become the shank of the steel pin, and an end portion, on which the point is formed in a further step. As known heretofore, the point is formed by rotary swaging or by so-called "pinch pointing", which refers to forging between two forging dies.

SUMMARY OF THE INVENTION In accordance with the present invention there is provided a method of making a steel pin, for axial, non-rotational penetration of a steel, concrete, or masonry substrate, from a predetermined length of carbon steel wire having an initial predetermined diameter, comprising the steps of: forming said predetermined length of carbon steel wire into a part which is elongate and which has two ends with a head on a first one of said ends of said part and a shank between said two ends of said part; rolling said part so as to form a point, conforming substantially to an ogive, upon a second one of said ends of said part whereby a pin is formed; and heat treating said pin so as to harden said pin.

Typically the pin is provided for axial, non-rotational penetration into a steel, concrete, or masonry substrate. A steel washer useful with the steel pin may also be provided, resulting in a fastener comprising the steel pin and the steel washer. The fastener is designed to be forcibly driven so that the steel pin is driven into a steel, concrete}or masonry substrate, either directly or through a workpiece.

Typically the steel pin is made from a predetermined length of carbon steel wire having an initial diameter and having a carbon content in a range from about the carbon content of AISI C 1038 steel to about the carbon content of AISI C 1065 steel. AISI C 1062 steel wire is preferred for the predetermined length of carbon steel wire. Broadly, the steel pin comprises a head, a tapered shank, a point, and a transition zone.

Typically the head of the steel pin has an outer diameter at least about 2.6 times greater than the initial diameter of the predetermined length of carbon steel wire.

Thus, the steel pin differs materially from the prior pin sold under Product Designation SBR 14, in which the head had an outer diameter about 2.3 times the initial diameter of the predetermined length of carbon steel wire used to make the prior pin sold thereunder. Heretofore, it was thought that the maximum diameter of the head of a pin in this carbon range was about 2.3 times the initial diameter, because the pins would be inconsistent due to na%fi®und heads or to cracks caused by over work-hardening.

The tapered shank of the steel pin defines a comparatively smaller conical angle and has a smaller end and a larger end. Its smaller end has a diameter smaller than the initial diameter of the predetermined length of carbon steel wire, preferably being about 0.6 times the initial diameter thereof. Preferably, the larger end of the tapered shank has a diameter about 0.7 times the initial diameter of the predetermined length of carbon steel wire. The tapered shank pin is especially useful in attaching to a bar joist because it develops sufficient holding power by continuously sizing the hole that it forms in the bar joist.

Being joined unitarily to the smaller end of the tapered shank, the point conforms substantially to an ogive, preferably to tangent ogive, which is tangent to the tapered shank. Although the point conforms substantially to an ogive, the point may have a rounded tip.

The transition zone has a tapered portion defining a comparatively larger conical angle between the tapered shank and the head. The tapered portion of the transition zone has a smaller end joined unitarily to the larger end of the tapered shank. The tapered portion thereof has a larger end joined unitarily to the head.

Preferably, the larger end of the tapered portion of the transition zone has a diameter about 1.1 times the initial diameter of the predetermined length of carbon steel wire. Preferably, the tapered shank defines a conical angle (total taper) in a range from about 2° to about 4°, and the axial length of the transition zone is less than about one half of the axial length of the tapered shank.

Typically the steel washer is annular and has an annular periphery and a central aperture, which has a margin with a novel configuration. The margin of the central aperture defines plural projections with pin-engaging surfaces spaced angularly from one another. Each pin-engaging surface conforms essentially to a cylindrical section. Collectively, the pin-engaging surfaces encompass a minor portion of a complete cylinder, not less than about one third of a complete cylinder.

Preferably, the margin of the central aperture of the washer defines exactly four of the pin-engaging surfaces, which are spaced regularly from one another. Preferably, moreover, each pin-engaging surface is configured so as to encompass about one twelfth of a complete cylinder.

The steel washer can be advantageously combined with a steel pin, such as the steel pin improved by this invention, to provide an improved fastener. In the improved fastener, the annular periphery of the washer has an outer diameter equal approximately to the outer diameter of the head and wherein the central aperture of the washer enables the washer to be tightly fitted over the tapered shank, near the smaller end of the tapered shank, when the pin and washer assembly is assembled. Thus, when the fastener is driven forcibly so that the pin is driven into a steel, concrete, or masonry substrate, the washer and the head are arranged to guide the fastener through the muzzle, barrel* or nosepiece of the driving or setting tool and the washer is arranged to be forcibly moved along the tapered shank, toward the larger end of the tapered shank, as the pin enters the substrate.

Typically the method of making a steel pin for axial, non-rotational penetration of steel, concrete, or masonry substrate, contemplates making the steel pin from a predetermined length of carbon steel wire with an initial diameter and with a carbon content in a range from about the carbon content of AISI C 1038 steel to about the carbon content of AISI C 1065 steel, preferably from a predetermined length of AISI C 1062 steel wire, by successive forming, rolling, and heat treating steps.

In the forming step, which may be also called a heading step, the predetermined length of carbon steel wire is formed so as to form an intermediate part, which is elongate and which has a head on one end and a shank between its ends. If the shank is tapered, it is generally tapered in the forming step. In the rolling step, the intermediate part is rolled so as to form a point conforming substantially to a tangent ogive, which is tangent to the shank, whereby a pin is formed. If the shank is knurled, it is knurled in the rolling step. In the heat treating step, the pin is hardened, preferably by austempering so as to provide the pin with a surface hardness of not greater than Rockwell C 52, preferably not greater than Rockwell C 48. The core hardness is preferably between Rockwell C 48 and Rockwell C 58. Optionally, the pin is decarburized in a conventional manner, after the rolling step, before the heat treating step.

These and other objects, features, and advantages of this invention are evident from the following description of a preferred mode for carrying out this invention, with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a fragmentary perspective view of a fastener comprising a steel pin and a steel washer as used to fasten a steel decking member to a steel bar joist.

Figure 2, on an enlarged scale, is an elevational view of the steel pin and a cross-sectional view of the steel washer, after the steel pin and the steel washer have been combined to provide the fastener and before the fastener has been driven.

Figure 3, on a similar scale, is an elevational view of an intermediate part, after a predetermined length of carbon steel wire has been formed to form the intermediate part and before the intermediate part has been rolled to form the steel pin.

Figure 4, on a similar scale, is a plan view of the steel washer, as seen from above.

Figure 5, on a similar scale, is a sectional view of the steel washer, as taken along line 5—5 of Figure 4, in a direction indicated by arrows.

Figure 6 is a further enlarged, fragmentary detail, as taken from Figure 4.

Figures 7, 8, and 9 are schematic views of initial, intermediate, and final stages in a rolling process, as seen from below, in which the intermediate part is rolled between two rolling dies to form the steel pin.

Figures 10, 11, and 12 are schematic views of the same stages of the rolling process, as seen from one end of the rolling dies.

DETAILED DESCRIPTION OF THE PREFERRED MODE As shown in Figure 1, an improved fastener 10 comprising a steel pin 100 in an improved form to be later described and a steel washer 200 in an improved form to be later described is useful for fastening a steel decking member 12, which is made from thin sheet steel oftentimes of 18 to 22 gauge, to a steel bar joist 14 of a thickness of 0.125 inch to about 0.1875 inch and a minimum tensile strength of 36,000 psi. Here, the decking member 12 is regarded as a workpiece, and the bar joist 14 is regarded as a substrate. The fastener 10 is shown in Figure 2, as assembled from the pin 100 and the washer 200, before the fastener 10 is driven.

In a preferred application of this invention, the fastener 10 can be forcibly driven by a fastener-driving tool, such as a powder-actuated tool, as exemplified by the powder-actuated, nosepiece-equipped, fastener-driving tool disclosed in Dewey et al. U.S. Patents No. 5,193,729, No. 5,199,506, and No. 5,199,625, the disclosures of which are incorporated herein by reference. If such a tool is used, the fastener 10 is sized to be axially guided in its nosepiece, in a manner to be later described.

In an alternative application of this invention, the fastener 10 can be forcibly driven by a powder-actuated, fastener-driving tool, as exemplified by the powder-actuated, muzzle-equipped, fastener-driving tool disclosed in Almeras et al. U.S. Patent No. 4,824,003, the disclosure of which is incorporated herein by reference. If such a tool is used, the fastener 10 is sized to enable the fastener 10 to be muzzle-loaded, in a manner disclosed therein.

Broadly, the steel pin 100 comprises a head 110, a shank 120, a point 130, and a transition zone 140 between the shank 120 and the head 110. The washer 200 is carried on the shank 120, in axially spaced relation to the head 110, and is movable toward the head 110 when the fastener 10 is driven forcibly through the decking member 12, into the bar joist 14, so that the washer 200 bears against the decking member 12.

The tapered shank 120 of the steel pin 100 defines a conical angle (total taper), preferably in a range from about 2° to about 4°, and has a knurled surface 122, a smaller end 124, and a larger end 126. The smaller end 124 has a diameter smaller than the initial diameter of the predetermined length of carbon steel wire, preferably being about 0.6 times the initial diameter thereof. The larger end 126 has a diameter about 0.7 times the initial diameter of the predetermined length of carbon steel wire.

Being joined unitarily to,the smaller end 124 of the tapered shank 120, the point 130 has a tip 132 and conforms except at the tip 132, which is rounded, substantially to a tangent ogive, which is tangent to the tapered shank 120.

Being between the tapered shank 120 and the head 110, the transition zone 140 has a tapered portion 142 defining a comparatively larger conical angle, preferably a conical angle (total taper) of about 40°. The tapered portion 142 has a smaller end 144 joined unitarily to the larger end 126 of the tapered shank 120. The tapered portion 142 has a larger end 146 joined unitarily to the head 110, via a circumferential fillet 148, which is regarded as an integral part of the transition zone 140.

The larger end of 146 of the tapered portion of the transition zone 140 has a diameter larger than the initial diameter of the predetermined length of carbon steel wire, preferably about 1.1 times the initial diameter thereof. The axial predetermined length of the transition zone 140, which includes the circumferential fillet 148, is less than about one half of the axial length of the tapered shank 120. It is convenient next to describe the material used to make the steel pin 100.

The steel pin 100 is made from a predetermined length of carbon steel wire, which has a carbon content in a range from about the carbon content of AISI C 1038 steel, which has a carbon content from 0.35 percent to 0.38 percent, to about the carbon content of AISI C 1065 steel, which has a carbon content from 0.60 percent to 0.70 percent. A high-manganese carbon steel having a carbon content in a similar range, such as AISI C 1562 high-manganese carbon steel, can be alternatively used. In a preferred mode for carrying out this invention, a predetermined length of AISI C 1062 steel wire is used, which has an initial diameter of about 0.208 inch.

In an alternative embodiment, such as a pin for fastening to thinner steel, a lower core hardness for the pin may be used, so that a lower carbon wire may be used to create the pin. Also, a more aggressive knurl may be preferred in this application, possibly a knurl with a slight helix.

In a preferred mode for carrying out this invention, the steel pin 100 has novel proportions, which may be conveniently referenced to the initial diameter of the predetermined length of carbon steel wire used to make the pin 100. The head 110 has an outer diameter at least about 2.6 times greater than the initial diameter of the predetermined length of carbon steel wire. The tapered shank 120 has a larger end 1 26, which has a diameter about 0.7 times the initial diameter of the predetermined length of carbon steel wire, and the larger end 146 of the tapered portion of the transition zone 140 has a diameter about 1.1 times the initial diameter of the predetermined length of carbon steel wire.

It is noted that since the larger end 146 of the tapered portion of the transition zone 140 has a diameter which is preferably about 1.1 times the initial diameter of the I | predetermined length of carbon steel wire, and furthermore, since the head 110 has an outer diameter which is at least 2.6 times greater than the initial diameter of the j predetermined length of carbon steel wire, then the outer diameter of the head 110 is approximately 2.35 times greater than the diameter of the larger end 146 of the tapered portion of the transition zone 140.

In an initial step, which is a forming step that may be also called a heading step and which is performed with conventional head-forming equipment for forming heads on pins or screws, the predetermined length of carbon steel wire is formed so as to form an intermediate part 150, which is elongate and has a headed end 152 and an opposite end 154. Suitable head-forming equipment is available commercially from National Machinery Company of Tiffin, Ohio, under Model 56.

As shown in Figure 3, the intermediate part 150 has the head 110, which is formed on the headed end 152, the shank 120, which is tapered but not yet knurled, the transition zone 140, which is disposed between the head 110 and the shank 120, and the opposite end 154. In a further step to be next described, the point 130 is formed on the opposite end 154, and the tapered shank 120 may be knurled. It is preferred for the tapered shank 120 to be knurled.

In the further step, which is a rolling step performed with conventional form-rolling equipment for rolling threads on screws, the intermediate part 150 is rolled between two rolling dies D1} D2, which employ the head 110 as a datum and which are configured suitably. Suitable form-rolling equipment is available commercially from E. W. Menn GmbH Maschinenfabrik of Hilgenbach, Germany, under Model GW 120-H.

As the rolling dies undergo relative movement from an initial stage shown schematically in Figures 7 and 10, through an intermediate stage shown schematically in Figures 8 and 11, to a final stage shown schematically in Figures 9 and 12, the intermediate part 150 is rolled so as to form the point 130 and so as to knurl the tapered shank 120, if the tapered shank 120 is to be knurled, whereby the pin 100 is formed. As formed in the rolling step, the point 130 has a tip 132 and conforms except at the tip 132, which is rounded, substantially to a tangent ogive, which is tangent to the tapered, knurled shank 120. A fragment 156 of the pointed end 154 is removed at the end of the die travel. It has been found that relatively long dies are preferable so that the movement of material in the pin is slow and the point of the pin is not overheated, and thus over work-hardened, whereby a uniform, smooth surface results, without laps or seams.

In a final step, which is an austempering step performed with conventional heat treating equipment, the pin 100 is austempered so as to have a surface hardness not greater than about Rockwell C 48, or not greater than about Rockwell C 52 if the tapered shank 120 is not knurled, and a core hardness in a range from about Rockwell C 48 to about Rockwell C 58. Suitable heat treating equipment is available commercially from numerous sources. Optionally, the pin 100 is decarburized in a conventional manner, after the rolling step, before the austempering step.

The steel washer 200 is stamped from a sheet of carbon steel, such as AISI C 1038 steel, which is preferred. Being annular, the washer 200 has an annular periphery 202 and a central aperture 210, which has a margin 212 with a novel configuration. The washer 200 is solid between the annular periphery 202 and the margin 212 of the central aperture 210. The margin 212 of the central aperture 210 defines four pin-engaging protrusions 214, which have concave pin-engaging surfaces 216, which are similar to one another, and which are spaced angularly and regularly from one another by four similar recesses 218. Before the washer 200 is fitted onto the pin 100, each pin-engaging surface 216 conforms essentially to a section of an imaginary cylinder of a given diameter. Each recess 218 conforms essentially to a section of an imaginary cylinder of a larger diameter.

Collectively, as contemplated by this invention, the pin-engaging surfaces 216 encompass a minor portion of a complete cylinder. As shown, in the preferred mode for carrying out this invention, each pin-engaging surface 216 encompasses about 30°, which is one twelfth of a complete cylinder. Collectively, in the preferred mode for carrying out this invention, the pin-engaging surfaces 216 encompass about one third of a complete cylinder.

In the improved fastener 10, the annular periphery 202 of the washer 200 has an outer diameter equal approximately to the outer diameter of the head 110 of the pin 100. Further, the central aperture 210 of the washer 200 enables the washer 200 to be tightly fitted over the tapered shank 120 of the pin 100, near the smaller end 124 of the tapered shank 120, when the fastener 10 is assembled.

Thus, there is sufficient contact area between the washer 200 and the tapered shank 1 2 such that when the fastener 10 is driven by a powder-actuated tool or an equivalent tool and is accelerated, the washer 200 does not move significantly along the tapered shank 120 but stays near the point 130. Being spaced axially, the washer 200 and the head 100 of the pin guide the fastener 10 without permitting the fastener 10 to tumble in the nosepiece of a nosepiece-equipped, fastener-driving tool, as discussed above.

Also, when the fastener 10 is driven, the washer 200 is arranged to be forcibly moved along the tapered shank 120, toward the larger end 126 of the tapered shank 120, when the washer 200 engages a workpiece or a substrate.

Because the pin-engaging surfaces 216 of the washer 200 encompass about one third of a complete cylinder, the pin-engaging surfaces 216 limit potential damage to the knurled surface 122 of the tapered shank 120 of the pin 100 when the washer 200 is moved along the tapered shank 120, toward the larger end 126 of the tapered shank 120.

Various modifications may be made in the preferred mode for carrying out this invention without departing from the scope and spirit of this invention. 11 !»

Claims (19)

CLAIMS: r(f 3^.^

1. A method of making a steel pin, for axial, non-rotational penetration of a steel, concrete, or masonry substrate, from a predetermined length of carbon steel wire having an initial predetermined diameter, comprising the steps of: forming said predetermined length of carbon steel wire into a part which is elongate and which has two ends with a head on a first one of said ends of said part and a shank between said two ends of said part; rolling said part so as to form a point, conforming substantially to an ogive, upon a second one of said ends of said part whereby a pin is formed; and heat treating said pin so as to harden said pin.

2. The method of claim 1 wherein the part is rolled so as to form the point conforming substantially to a tangent ogive, which is tangent to the shank.

3. The method of claim 1 or 2 wherein the heat treating step comprises austempering the pin so as to provide the pin with a surface hardness not greater than about Rockwell C 48.

4. The method of any one of the preceding claims wherein the heat treating step comprises austempering the pin so as to provide the pin with a core hardness in a range from about Rockwell C 48 to about Rockwell C 58.

5. The method of any one of the preceding claims wherein the heat treating step comprises austempering the pin so as to provide the pin with a surface hardness not greater than about Rockwell C 48 and with a core hardness in a range from about Rockwell C 48 to about Rockwell C 58.

6. The method of claim 5 wherein the predetermined length of carbon steel wire is formed in the forming step so that the head has an outer diameter at least about 2.6 times greater than the initial predetermined diameter of the predetermined length of carbon steel wire.

7. The method of claim 6 wherein the predetermined length of steel wire is formed in the forming step so that the shank is tapered between a larger end, which is nearer to the head, and a smaller end, at which the point is formed.

8. The method of claim 7 wherein the predetermined length of carbon steel wire is formed in the forming step so that the smaller end of the tapered shank has a diameter about 0.6 times the initial predetermined diameter of the carbon steel wire.

9. The method of claim 8 wherein the predetermined length of carbon steel wire is formed in the forming step so that the part has a transition zone having a tapered portion with a smaller end, which is joined unitarily with the larger end of the tapered shank, and with a larger end, which is joined unitarily to the head.

10. The method of claim 9 wherein the predetermined length of carbon steel wire is formed in the forming step so that the larger end of the tapered portion of the transition zone has a diameter greater than the initial predetermined diameter of the predetermined length of carbon steel wire.

11. The method of claim 10 wherein the predetermined length of carbon steel wire is formed in the forming step so that the larger end of the tapered shank has a diameter about 0.7 times the initial predetermined diameter of the predetermined length of carbon steel wire and wherein the larger end of the tapered portion of the transition zone has a diameter about 1.1 times the initial diameter of the predetermined length of carbon steel wire.

12. The method of any one of the preceding claims wherein the predetermined length of carbon steel wire is rolled in the rolling step so that the shank is knurled between the larger and smaller ends of the shank.

13. The method of any one of the preceding claims wherein the pin is formed from a predetermined length of AISI C 1062 steel wire.

14. The method of claim 13 wherein the predetermined length of AISI C 1062 steel wire is rolled in the rolling step so that the shank is knurled between the larger and smaller ends of the shank.

15. The method of any one of the preceding claims wherein the pin is formed from a predetermined length of high-manganese carbon steel wire having a carbon content in the same range.

16. The method as set forth in any one of the preceding claims, further comprising: fabricating said pin from carbon steel wire which has a carbon content which is within a range of from about the carbon content of AISI C 1038 steel to about the 13 bO 0 7 67 carbon content of AISI C 1062 steel.

17. A method as claimed in claim 1 substantially as herein described.

18. A method of forming a pin substantially as herein described with reference to figure 3 and figures 7 to 1 2 of the accompanying drawings.

19. A pin formed by the method of any one of the preceding claims. Illinois Tool Works, Inc. By Its Attorneys BALDWIN SHELSTON WATERS rH0 OF CLAIMS