The present invention relates generally to concrete casting methods and apparatus, and particularly to methods and apparatus for casting elongated prestressed concrete structures, e.g., utility poles. More specifically, the invention concerns the casting of prestressed concrete utility poles of octagonal cross-section.
Concrete casting of utility poles, e.g., poles used for supporting lighting fixtures and/or utility lines, is known. Such elongated structures have been cast in various cross-sectional shapes, e.g., circular, rectangular and octagonal. In a conventional process, concrete slurry is poured into a mold having the desired shape and is allowed to cure before removal of the mold from the casting (or removal of the casting from the mold). Typically, the mold contains reinforcement elements, e.g., rebar running longitudinally within the mold, that become part of the cast product and impart additional tensile strength to the cast concrete (which by itself has high compressive strength but very low tensile strength).
The assignee of the present application has, for more than a year, commercially produced rebar reinforced (non-prestressed) octagonal concrete lighting poles employing a clamshell-type mold form. In this process, the clamshell-type mold form is closed onto an elongated rail (i.e., pallet) supported on a pair of light-duty saw horse-like supports formed from lengths of angle iron. An octagonally shaped mold cavity is formed with the pallet top surface forming a lower surface of the resultant mold; the clamshell-type mold form forms six additional mold surfaces and an open top along which the eighth surface of the casting is formed. Concrete is poured and allowed to cure. Once the concrete has firmed-up, hinged halves of the clamshell-type mold form may be opened to permit lateral removal of the mold form from the casting. The mold form can be reused while the casting continues to cure on the pallet. Once curing is substantially complete, the casting may be removed from the pallet for finishing operations, storage, transportation, etc.
Cast concrete structures with substantially increased tensile strength can be obtained through known concrete prestressing techniques. Generally, in such known techniques, concrete is poured around high strength steel wires, cables or rods which are kept under considerable tension until the concrete has substantially completely set. The wires are then cut, and compressive forces are thereby imparted to the concrete through the bond between the steel and concrete. Additional tensile strength in the cast product results from the fact that when the structure receives a load, the compression imparted to the concrete by the prestressing elements is relieved on that portion that would otherwise be put into in tension by the load. In order to assure a strong bond between the tensioned steel wires and the concrete (which is required to avoid slippage), it is necessary to permit the casting to substantially completely cure before the tensioning elements are cut or otherwise disconnected from the tensioning fixture.
For certain high load applications, such as utility and lighting poles to be used in regions susceptible to high winds, e.g., hurricanes, the substantially greater structural strength afforded by prestressed concrete is highly desirable. As compared with conventional reinforced concrete casting operations, however, known industry techniques for casting prestressed concrete poles are labor and time intensive, and require additional materials (e.g., stressing elements) and costly casting (and tensioning) apparatus.
Pour casting into an open-top mold incorporating prestressing elements has been used to form prestressed concrete structures. As noted above, however, in such processes it has been necessary for the casting to remain in the mold form until the casting is substantially cured, in order to avoid slippage of the tensioned prestressing elements within the concrete. This may take between 16 and 20 hours. With the mold form occupied for this lengthy period of time, production rates per mold form are necessarily very low. To achieve higher production rates, it is necessary to employ additional mold forms (and associated tensioning apparatus), at concomitantly greater expense. Additionally, with apparatus known in the industry, castings having a cross-sectional dimension that reaches a maximum between opposed sides of the casting, e.g., octagonal poles, cannot easily be removed laterally from a mold cavity. Rather, removal of this type of casting from its mold cavity requires either an involved disassembly of the mold form, or an endwise removal operation, i.e., a longitudinal extraction of the casting from the mold form. In order to permit an endwise removal operation, an end wall of the mold form must be disassembled and removed. If the ends of the mold form are reinforced and specially configured to serve also as pretensioning headers, such a removal operation can to be difficult.
Centrifugal (spin) casting can be carried out to cast poles within a mold including tensioned prestressing elements. Such apparatus tend to be very costly, however.
The following patents teach particular apparatus and methods for casting elongated prestressed concrete products utilizing a mold form positioned between, or incorporating therein, headers of a wire pretensioning fixture:
COLLIER U.S. Pat. No. 832,594
DEIGAARD U.S. Pat. No. 3,269,494
CAZENAVE et al. U.S. Pat. No. 4,758,393
COLLIER discloses a mold forming a pair of opposed cavities of L-shaped cross-section, along which wires pretensioned between end brackets extend. Once the casting is set, the tensioned wires are severed at their ends, and the castings (angle posts) are removed from the mold box.
DEIGAARD discloses a mold form of rectangular cross-section intended for casting concrete poles having a longitudinal opening therethrough. The mold form is positioned within a wire pretensioning apparatus including an elongated very heavy base, which is preferably made of concrete and partially embedded in the ground. Pretensioning wires are extended between a pair of headers. The mold form itself is a multi-part open top structure. Once the concrete has hardened to such a point that engagement of the concrete with the tensioned cables will prevent any movement of the cables within the concrete, the cables are cut and the side plates of the mold are dismantled and removed.
CAZENAVE et al. disclose a mold form (“impression”) separable from a wire tensioning frame for use in making beams of prestressed concrete. Separability of the impression from the tensioning frame permits removal of the impression from the casting (and tensioning frame) for reuse in casting another beam while the first beam begins to dry. In the disclosed process, the tensioning frame is placed on the impression. Concrete is cast into the mold constituted by the combination of the frame and the impression. The concrete and the mold is vibrated and “rammed.” Then, the impression is flipped over together with the tensioning frame, and the impression is removed from the partially cured casting for reuse. The mold form nests within the tensioning frame; the frame comprises sides and ends but no central floor.
In view of the foregoing, it is a principal object of the present invention to provide improved apparatus and methods for casting prestressed concrete products, particularly prestressed concrete utility poles and like elongated concrete structures.
It is a more specific object of the invention to provide apparatus and methods for casting elongated prestressed concrete structures, which improve production efficiency by permitting reuse of a mold form while a first casting is left undisturbed to continue to cure in a pretensioning fixture that remains stationary.
It is yet another object of the invention to reduce equipment costs by enabling a prestressed concrete pole casting operation to be carried out using clamshell-type mold forms of the same general type previously used for casting non-prestressed concrete poles.
It is a further object of the invention to provide a prestressing element pretensioning fixture of simple easy to use construction, and great strength/rigidity for withstanding considerable wire pretensioning forces, which fixture is usable together with a clamshell-type mold form in such a manner that the form is easily properly locatable on the pretensioning fixture for pouring and initial curing, and easily removable from the pretensioning fixture without disturbing the casting, to thereby permit the casting to continue to cure in the pretensioning fixture during reuse of the mold form.
One or more of the above-stated objects are achieved in accordance with the present invention, by a method of casting elongated prestressed concrete products. A clamshell-type mold form, including two hinged mold halves, is positioned on a first prestressing element pretensioning fixture. The mold halves are closed together over a set of prestressing elements pretensioned in the pretensioning fixture, to form a mold cavity with the prestressing elements extending therealong. Concrete slurry is dispensed into the mold cavity. The concrete slurry is permitted to cure, to thereby form a concrete casting. The mold halves are opened and the mold form is removed from the casting and the pretensioning fixture, after the casting has partially cured. The casting remains on the pretensioning fixture, and the pretensioning fixture remains stationary, during removal of the mold form. The casting is permitted to continue to cure on the pretensioning fixture after removal of the mold form, at least to such point that engagement of the concrete with the pretensioned prestressing elements will prevent movement of the prestressing elements within the concrete. Thereafter, the prestressing elements are released from the pretensioning fixture.
In a second aspect, the invention resides in a production system for carrying out the method described above. The system includes multiple pretensioning fixtures, a clamshell-type mold form, and an overhead conveyor for transporting the mold form as a unit from one of the pretensioning fixtures to another.
In a third aspect, the invention is embodied in a wire pretensioning fixture for use in casting elongated prestressed concrete structures. The fixture comprises a pair of elongated I-beams joined together in side-by-side relation to form a mold form-supporting base. A pair of upstanding headers are provided, one secured at each end of the base. At least one of the headers includes an anchor plate to which ends of tensioned prestressing elements may be secured. The anchor plate is secured between a pair of generally L-shaped side plates having base portions thereof fitted and secured within spaces defined between respective pairs of upper and lower I-beam flanges.
In a fourth aspect, the invention is embodied in an apparatus for casting elongated prestressed concrete products. A pretensioning fixture includes a pair of spaced headers between which prestressing elements may be pretensioned. A clamshell-type mold form including two hinged mold halves is removably positionable on the pretensioning fixture to thereby form a mold cavity along which prestressing elements pretensioned between the headers may extend.
The above and other objects, features and advantages of the present invention will be readily apparent and fully understood from the following detailed description of preferred embodiments, taken in connection with the appended drawings.
As seen in
Also seen in
Advantageously, clamshell-type mold form 3 is usable together with pretensioning fixture 1 in such a manner that form 3 is easily properly locatable on, and removable from, pretensioning fixture 1 by way of conveyor system 5, while pretensioning fixture 1 remains stationary. By maintaining pretensioning fixture 1 stationary, the integrity and stability of the pretensioning fixture under the considerable forces set-up upon pretensioning the cables 6 is substantially increased. In accordance with the invention, one casting is permitted to remain stationary and continue to cure in pretensioning fixture 1, while mold form 3 is removed and replaced on another pretensioning fixture, for carrying out a subsequent casting operation.
Pretensioning fixture 1 has an elegant construction of great strength and rigidity for withstanding substantial cable pretensioning forces. As seen clearly in
The headers are arranged in general mirror image relation with each other. Each is preferably formed of a pair of upstanding generally L-shaped side plates 13a, 13b; 15a, 15b. A third (anchor) plate 13c, 15c extends orthogonally between the respective pairs of side plates, in or adjacent a vertical plane passing through the inside corners defined by the side plates' L-shape. The horizontally extending leg (base) portion of each L-shaped side plate 13a, 13b; 15a, 15b is made to fit within the space defined between a respective pair of upper and lower I-beam flanges 9a, 9b; 11a, 11b, and is welded to the same along its upper and lower edges. I-beams 9, 11 terminate at the aforesaid vertical plane, such that upper I-beam flanges 9a, 11a fit into the inside corners defined by the side plates' L-shape. This integral construction of adjoined I-beams 9, 11 and headers 13, 15 is elegant in its simplicity and in the great strength and rigidity it affords for withstanding the considerable forces set-up by the pretensioning of cables 6.
Header 15 is located at a core insertion end of pretensioning fixture 1, and is illustrated more clearly in
In a preferred embodiment, pretensioning fixture 1 is sized and configured such that the distance between the two anchor plates 13c, 15c is approximately two feet greater than the length of the pole to be cast. This extra length serves to accommodate mold end plate assemblies, and to provide clearances for cutting the cables, as will be described.
The inventive casting apparatus preferably further includes a rail-like structure (“pallet”) 19 extending along and secured to a central upper surface of base 7. In the preferred embodiment, pallet 19 is a generally rectangular structure formed from angle iron or the like. Pallet 19 is centered on base 8 and bridges an upper weld seam 20 connecting the pair of I-beams 9, 11. As best seen in
Pallet 19 has an upper horizontal surface 23 that serves as a lower face of the octagonal mold. In addition, vertical side surfaces 25, 27 of pallet 19 serve to provide mounting locations against which lower portions of opposing halves of mold form 3 may engage. Referring to
As seen in
By inclusion of the above-described mold locating and lock-down means, including holes 31 for receiving pins 29 and bolts 33, and lifting/spreader arm extensions providing slots 38 for receiving swinging clamps 33, mold form 3 of the invention represents an advantageous adaption of the mold form previously used to cast non-prestressed concrete poles (see the Background section) which is well suited for the casting of high quality prestressed concrete poles.
Clamshell-type mold form 3 is now described in further detail. Mold form halves 3a, 3b are hingedly connected to each other by a series of spaced lifting/spreader arms 39. In a preferred embodiment, and as shown in
As best seen in
To pretension cables 6 in pretensioning apparatus 1, the cables are first passed through one of the anchor plates, e.g., anchor plate 13c, threaded through a first mold end plate 53 (see
In the illustrated exemplary method and apparatus for casting concrete poles of octagonal cross-section, each of the four cables is preferably tensioned to approximately 28,900 lbs. This results in a bending moment acting on the opposite ends of adjoined I-beams 9, 11 of approximately 246,000 ft.-lbs. The I-beams should be able to withstand this load with a maximum deflection of 0.01 in. Additional strength and rigidity of pretensioning apparatus 1 is preferably obtained through the use of steel brackets 57 bolted to a reinforced concrete foundation (which is preferably 8″–10″ thick) and welded, respectively, to a bottom platform 59 of each header 13, the L-shaped side plates, and at spaced locations along the lengths of the lower I-beam flanges 9b, 11b.
Once cables 6 are pretensioned on pretensioning fixture 1, core 7 is inserted endwise through anchor plate aperture 17, and a corresponding aperture 61 provided in mold end plate 55. Then, core 7 is advanced along base 5, centered within the set of four tensioned cables 6, and is preferably threaded through a series of reinforcing hoops 80, 82, which are ultimately wrapped about the cables at opposite end portions of the mold cavity, as seen in
Set-up of mold form 3 for casting is a simple matter of pivoting mold halves 3a, 3b to an open position, lowering the mold form 3 over the set of cables 6 pretensioned in fixture 1, closing the mold halves over cables 6 and locating and removably securing the mold halves to the side surfaces 25, 27 of pallet 19. The locating and securing is preferably accomplished by way of previously described pins 29, bolts 33 and swing-up clamps 37.
In order to complete formation of an octagonal mold cavity along which tensioned cables 6 extend, the open ends of the tubular structure formed by the mold form/pallet combination are closed-off by securement of rectangular end plates 53, 55 against end frame plates 49a, 49b at each end of mold form halves 3a, 3b. As shown in
Next, as seen in
As illustrated in
Following pouring and vibration, the slurry is allowed to begin to set-up. Mold core 7 should be removed within 20–30 minutes following the pour, to avoid excessive adhesion of the concrete thereto. Once the casting has become firm (typically after approximately 2–3 hours), clamshell mold form 3 may be removed from the resultant casting and pretensioning fixture 1. In accordance with the invention, removal of mold form 3 is carried out while the casting remains secured on pretensioning fixture 1 by cables 6, which remain tensioned between headers 13, 15. This permits mold form 3 to be removed for reuse, without waiting for the casting to cure to the point at which the prestressing cables are securely engaged within the concrete.
Removal of mold form 3 is accomplished essentially by reversing the mold form set-up steps previously described, i.e., by removing retaining structures 65 and any secondary mold cores 69, releasing mold form 3a, 3b from the mold end plates 53, 55, and pallet 19, then opening mold form 3 and withdrawing it vertically. Advantageously, the vertical mold form placement and removal operations can be carried out by lowering and raising the clamshell-type mold form (as a unit) with overhead conveyor system 5. Conveyor system 5 is also advantageously used to relocate mold form 3 onto another pretensioning fixture, where a subsequent casting operation can be carried out while the first casting continues to cure on its pretensioning fixture 1. The casting is thus permitted to continue to cure, at least to the point at which a secure engagement of the concrete with the cables is obtained, so as to prevent any movement of cables 6 within the concrete once cables 6 are cut or otherwise released from the pretensioning fixture. Once sufficient curing has taken place, cables 6 are preferably released from pretensioning fixture 1 by cutting (e.g., with a welding torch). Cutting is carried out within the clearances provided between the mold end plates 53, 55 and their respective anchor plates 13c, 15c. Thereafter, the casting can be removed for finishing operations, storage, transportation, etc.
A prestressed concrete light pole 73 successfully cast with the method and apparatus of the invention is shown in
The incorporated prestressing elements are multi-strand steel cables: four ½″ diameter P.T. strands (270 Grade, Lo-Lax ASTM A-416), pretensioned, respectively, to 28,900 lbs. The top ten feet of the cables masked (i.e., covered) to prevent grip of the cable with the concrete at the relatively thin top portion of the tapered pole. Fifteen #3 hoops 80 at 4″ spacings (see
Poles 73, cast with ASTM specification ready-mixed concrete (C94), conform with P.R.E.P.A. specifications for concrete poles. The minimum compressive strength for the concrete used was 5,000 psi, determined in accordance with the ASTM method of test for compressive strength of molded concrete cylinders (C39—tests to be performed at 28 days). The poles are rated at a maximum wind load of 125 M.P.H., an ultimate resisting moment of 34,570 ft.-lb., and a working moment 17,285 ft-lb. (standard PCI testing with lateral load applied 2′ from pole tip, and base of pole buried to 5′; 2.5 ft2 projected accessories surface area).
As shown in
From the foregoing, it will be appreciated that the invention can greatly improve production efficiency relative to prior art prestressed concrete casting methods requiring the mold form to remain on the casting until the casting is substantially completely cured. Difficulties associated with movement of the pretensioning apparatus to obtain release of the casting are also avoided.
The present invention has been described in terms of preferred and exemplary embodiments thereof. Numerous other embodiments, modifications and variations within the scope and spirit of the appended claims will occur to persons of ordinary skill in the art from a review of this disclosure.
This application is a divisional of U.S. application Ser. No. 09/812,595, filed Mar. 21, 2001, now U.S. Pat. No. 6,773,650.
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Number | Date | Country | |
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Parent | 09812595 | Mar 2001 | US |
Child | 10876637 | US |