METHOD FOR HOT FORGING THREADS INTO AN END OF A STEEL BAR

Information

  • Patent Application
  • 20140325815
  • Publication Number
    20140325815
  • Date Filed
    May 04, 2013
    11 years ago
  • Date Published
    November 06, 2014
    10 years ago
Abstract
A method tor hoi forging at least one end of a steel reinforcing bar (i.e., a rebar) to simultaneously form a wide head and threads funning around the head during a single step whereby to enable the bar to be coupled end-to-end an adjacent steel bar to be used, for example, to reinforce a precast concrete structure. The end of the bar is first preheated, and the heated end is surrounded by a closing die having a threaded geometry. The die is then nested within and closed around the heated end by an annulus ring of a hydraulic press, or the like. A hydraulic ram of the press is moved through the annulus ring and into engagement with the heated end of the rod so as to apply a compressive force thereto. The metal of the heated end flows into the die so as to be enlarged therein and assume the threaded geometry of the die.
Description
BACKGROUND OF THE INVENTION

1. Field of the Invention


The invention relates to a method for hot forging at least one end of a steel reinforcing bar (commonly referred to as a rebar), or the like, so as to form an enlarged threaded head during a single step. The threaded head of the rebar is adapted to be connected to an opposing threaded rebar by means of a suitable threaded coupler to be used, for example, to reinforce a precast concrete structure.


2. Background Art


From time-to-time, it becomes necessary to connect one steel bar to another. By way of example, in the ease of concrete construction or repair, a plurality of steel reinforcing bars are connected end-to-end to be embedded within a precast concrete structure to enhance the strength of the structure and enable the structure to avoid shifting relative to an adjacent structure and better withstand the effects of an earthquake and other natural forces. Opposite ends of a pair of axially-aligned rebars are connected together by means of a coupler located therebetween. In this case, the opposing ends of the rebars to be connected together are threaded during a cold working process by either rolling or cutting the threads into the bars. The threaded ends of the rebars are rotated into mating engagement with a correspondingly threaded coupler. To maximize the cross-sectional (i.e., tensile) property of the bars, the threaded end of each can be enlarged prior to threading by either one of an independent cold or hot forming or forging step. In this case, the bar is provided with a relatively wide upset head often known in the art as a button or mushroom head.


It would be desirable to combine the advantages of upsetting and threading one or both ends of a rebar or the like during an efficient one-step process so as to eliminate the need to perform the separate and time-consuming independent steps in the manner described above.


SUMMARY OF THE INVENTION

Briefly, and in general terms, a method is disclosed for hot forging at least one end of a steel reinforcing bar (i.e., a rebar) or the like so as to form an enlarged threaded head during a single step. By virtue of the foregoing, the rebar can be headed without being subjected to the conventional inefficient and independent steps of first upsetting the rebar and then cold-working the upset end by roiling or cutting threads there within. A rebar having an end which is both enlarged and threaded according to the method herein disclosed can he connected end-to-end an adjacent axially-aligned similar rebar by rotating the opposing threaded ends of the rebars into mating engagement with a correspondingly threaded coupler located therebetween.


According to a preferred embodiment, one end of a rebar to be treated during a hot forging method is preheated to a temperature of about 2000° F. A clamp grips the rebar to prevent a displacement thereof during the hot forging method. The preheated end is located inside a pair of conical closing dies that are dimensioned to permit expansion and provide the heated end with a clearly defined threaded geometry. By way of example, a hydraulic press moves towards and generates a pushing force to compress the preheated end for causing the metal to flow into threaded cavities within the dies so as to assume the threaded geometry thereof. That is, with the dies closed around the rebar, a ram from the hydraulic press moves against and applies a pushing force to the pre-heated end. Accordingly, the preheated end is simultaneously compressed, shortened, widened and threaded to match the geometry of the die cavities. At the conclusion of the hot forging step just explained, the rebar is provided with an enlarged (i.e., widened) head having a series of threads running therearound, whereby the rebar is adapted to be mated to a suitable coupler for end-to-end connection to an adjacent rebar to be used, for example, to reinforce a concrete structure.





BRIEF DESCRIPTION OF THE DRAWINGS


FIG. 1 shows a conventional rebar of the kind used to reinforce a concrete structure;



FIG. 2 shows a rebar having a wide and threaded head at one end thereof following a hot forging method according to a preferred embodiment of the present invention;



FIG. 3 shows a pair of rebars like that shown in FIG. 2 connected end-to-end one another by means of a coupler located therebetween; and



FIGS. 4 and 5 illustrate a preheated end of a rebar during the hot forging method of this invention to produce an enlarged head having threads formed therewithin so as to be suitable for coupling to an adjacent rebar.





DESCRIPTION OF THE PREFERRED EMBODIMENT


FIG. 1 of the drawings shows a conventional steel reinforcement bar 1 (commonly known as a rebar). The rebar 1 is of the kind to be embedded within a reinforced concrete structure (e.g., a wall a panel, or the like) or connected between existing and adjacent reinforced concrete structures. A plurality of such rebars connected end-to-end one another enable a new structure to be built or an adjacent structure to be added to an existing structure. As a result of interconnecting a plurality of re-bars like that shown in FIG. 1, the reinforced structure or structures are less likely to shift (e.g., during an earthquake) so that their ability to avoid degradation and the necessity for an early repair will be enhanced.


In accordance with the present improvement, in order to connect the opposing ends of a pair of adjacent and axially-aligned rebars or any other bars that are similar thereto, the ends of the rebars are enlarged (i.e., widened) to maximize their tensile strength and threaded during a single hot forging step. Referring in this regard to FIG. 2 of the drawings, a rebar 10 is shown after at least one end thereof has been enlarged and threaded. By virtue of the foregoing, the rebar 10 can be quickly and reliably connected by mans of a suitable threaded, coupler (designated 30 in FIG, 3) end-to-end an adjacent rebar.


The rebar 10 of FIG. 2 is shown having an elongated cylindrical body 12. In the preferred embodiment, a first end of the rebar 10 is subjected to a hot forging step, whereby to create an enlarged head 14 having a series of threads 16 running therearound. Depending upon the application and location of the rebar 10, either one or both ends can be enlarged and threaded. The number of threads 16 formed in the head 14 of rebar 10 can vary depending upon application. While the diameter of the enlarged head 14 can also vary, increasing the diameter will correspondingly increase the load capacity of the rebar 10. The diameter of the enlarged head 14 should be bigger (i.e., wider) than the diameter of the cylindrical body 12 so that the rebar 10 can be efficiently coupled to m adjacent and axially-aligned rebar (designated 20 in FIG. 3).


To this end, FIG. 3 of the drawings shows a pair of rebars 10 and 20, each having an enlarged head 14 and 24 with a number of threads 16 and 26 formed therewithin. The enlarged and threaded heads 14 and 24 of the rebars 10 and 20 are rotated into mating engagement with a correspondingly threaded cylindrical bore 28 of a coupler 30 such that the rebars are connected end-to-end one another. In this same regard, the enlarged threaded head (e.g., 14) of the rebar 10 can. be coupled to a variety of other connectors or fittings, such as end bearing anchors, nuts, etc.


A preferred method for making the enlarged head 14 and the threads 16 formed therein at one end of the rebar 10 of FIG. 2 during a single step is now described. As opposed to the conventional sequential and independent upsetting and cold-working threading steps, the rebar 10 is subjected to a single hot forging step. In this case, and referring now to FIGS. 4 and 5 of the drawings, the end of rebar 10 to be treated is first preheated to a temperature of about 2000° F. at which the rebar will melt. Any suitable heating source, such as an induction or gas source, can be used for this purpose. The end of the rebar body 12 which lies opposite the heated end is gripped and held stationary by a clamp 34, or the like. The heated end of the rebar 10 is then located inside a pair of corneal closing dies 32. Each die 32 has a cavity 33 that is dimensioned to permit an expansion of the heated end in response to a compressive force and provide the heated end with a clearly defined threaded geometry to enable the resulting enlarged head 14 (best shown in FIG. 5) to be mated to a coupler, fitting or connector such as that designated 30 in FIG. 3.


A conventional hydraulic press 40 may be used to generate a pushing force to be applied to and compress the preheated end of the rebar 10 and thereby cause the metal to flow into the cavities 33 of the dies 32 and assume the threaded geometry thereof. More particularly, the hydraulic press 40 moves towards the rebar 10 until the conical dies 32 are nested within and embraced by a conical annulus ring 36 of the press, whereby the dies are automatically closed around the preheated end. A hydraulic ram 38 is then moved axially through the annulus ring 36 towards the rebar 10. With the body 12 of the rebar 10 being held stationary by the clamp 34, the axial pushing force applied by the ram 38 causes the preheated end to be simultaneously compressed, shortened, widened and threaded to match the geometry of the threaded cavities 33 of dies 32. By virtue of the foregoing, the rebar 10 is provided with an enlarged head 14 having a series of threads 16 formed therein as shown in FIG. 2 without having to cut or roll the threads into the rebar daring a separate cold working step.


The ram 38 is now withdrawn and the pushing force against the enlarged head 14 is terminated. The pair of dies 32 opens, and the clamp 34 releases its grip of the rebar body 12. Once it cools, the enlarged and threaded rebar 10 will be ready for use in reinforced concrete construction as described above as well as for any other application in which steel reinforcing bars or similar bars are to be connected to one another.

Claims
  • 1. A hot forging method for threading at least one end of a steel rod to enable the rod to be coupled to an adjacent steel rod, said method comprising the steps of: heating the end of the steel rod;surrounding the heated end of the steel rod by a die having a threaded geometry;applying a compressive force to the heated end of the steel rod to cause the heated end to expand and assume the threaded geometry of the die; andremoving the heated end of the steel rod from the die and permitting the threads formed therein to cool.
  • 2. The hot forging method recited in claim 1, wherein said die has a threaded cavity into which the heated end of said steel rod flows and expands in response to said compressive force being applied to said heated end, whereby the heated end is simultaneously enlarged and threaded within the threaded cavity of said die during said step of applying said compressive force to said heated end.
  • 3. The hot forging method recited in claim 2, wherein said steel rod has an elongated body, each of the threaded cavity of said die and the enlarged end of said steel rod being wider than said elongated body.
  • 4. The hot forging method recited in claim 1, wherein said die includes at least a pair of conical closing die members having respective threaded cavities, said method including the additional step of closing said pair of die members around the healed end of said steel rod, whereby said heated end is simultaneously enlarged and threaded corresponding to the size and geometry of the threaded cavities of the die members of said die.
  • 5. The hot forging method recited in claim 4, including the additional step of locating said die within a press; and said press applying a compressive force to said die for closing the pair of conical die members thereof around the heated end of said steel rod.
  • 6. The hot forging method recited in claim 5, including the additional step of nesting said die within a conical annulus ring of said press during the step of locating said die within said press, whereby said die is embraced by said conical annulus ring for applying said compressive force to said die to close said pair of conical die members.
  • 7. The hot forging method recited in claim 6, including the additional step of moving a ram of said press through said conical annulus ring and into contact with the heated end of said steel rod tor applying said compressing force thereto and thereby causing said heated end to simultaneously expand into the threaded cavities of the die members of said die and assume the threaded geometry of said cavities.
  • 8. The hot forging method recited in claim 7, including the additional step of gripping and holding said steel rod to resist a displacement thereof during the step of the ram of said press applying said compressive force to the heated end of said rod.
  • 9. The hot forging method recited in claim 1, wherein said steel rod is a rebar.
  • 10. The hot forging method recited in claim 1, including the additional step of rotating the threaded end of said steel rod into mating engagement with a coupler having a threaded bore running therethrough.