Composite pipeline

This invention relates to a composite pipeline to be used in a submerged condition, usually in deep water. In accordance with this invention, the composite pipeline comprises a pipeline through which a fluid flows, e.g., oil, gas or a slurry; to provide for electrolytic protection, the pipeline includes a suitable coating or wrapping; finally, to enable the pipeline to be maintained in a submerged condition, an outer coating of concrete is provided about the wrapping. Further and in accordance with this invention, the concrete coating is integrally bonded to the pipeline in such fashion that the three element structure so provided can be said to be a composite structure rather than one made up of three separate elements. Because the composite structure pipeline is structurally one, it is possible to use a lighter weight of material in the pipeline with the result that a saving of as much as two-thirds of the pipeline weight is achieved.

It has been known heretofore to apply concrete to a pipeline to maintain the latter submerged in water. However, heretofore the concrete has merely been provided in such a manner that it only served as a weight to overcome the buoyant effect of the pipeline and to keep the pipeline from moving under the action of waves and current. The concrete was not considered to contribute to the structural integrity of the pipeline, only having sufficient structural strength to withstand the handling loads during installation and to remain intact during the life expectancy of the pipeline while in its final laid position.

SUMMARY OF THE INVENTION

The composite pipeline of this invention provides several economic advantages. Thus up to two-thirds of the material used in the pipeline can be eliminated to provide a composite pipeline comparable to those in use at the present time. Further, up to half the manhours are eliminated in fabricating the carrier and further, the time required to string and lay the pipeline is reduced by at least half.

By utilizing the composite pipeline of this invention, the pipe wrap and the weight coating jacket contribute to both the strength and rigidity of the pipe which they surround. The numerical calculations in determining the strength and rigidity of the pipeline are closer to what is actually experienced in laying operations and by tests than was possible before the present invention. Finally, the abrasion of the wrap by the weight coating jacket is virtually eliminated, thus enhancing the life expectancy of the barrier to electrical currents and corrosion which are detrimental to the life expectancy of the pipeline. Further, a closer balance of design is achieved in the pipeline for all the loading conditions on the pipeline throughout its useful life. Finally, all materials used in the pipeline act as a structural unit for the critical loading conditions, rather than independently, as is the case in present pipelines.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is a side elevation showing a position of the pipeline of this invention in use and wherein a portion of the pipeline lays on the sea floor with at least one end extending to above the surface of the sea.

FIGS. 2, 3 and 4 are, respectively, perspectives showing various modifications of the composite pipeline of this invention.

FIGS. 5, 6 and 7 are, respectively, sections taken through the structures shown in FIGS. 2, 3 and 4.

DESCRIPTION OF THE PREFERRED EMBODIMENT

In the preferred embodiment, the composite pipeline includes the pipe 6 which may be of metal plastic or other suitable material. Applied about the surface of the pipe is a coating or wrap 7 to protect the pipeline against electrolytic corrosion. One coating is made of two layers of glass fiber held in place with either a coal tar or a bitumastic binder and applied as a coating.

In accordance with this invention, an outer layer of concrete, generally indicated at 8, is applied over the coating or wrap and in such fashion that, together with the pipeline, they form a composite structure. This is achieved by utilizing shear transfer devices between the pipe and the concrete. These can be mechanical means such as spiral wire 9 as shown in FIGS. 2 3 and 4, expanded metal 10 as in FIGS. 3 and 6 or shear lugs 11 as in FIG. 3. These are secured in place on the pipe by welding or with an adhesive before coating or wrap and the concrete are applied. One can also use a structural adhesive 12 as in FIG. 4, either in lieu of the coating or wrap or in conjunction with the coating or wrap, and which bonds to the steel and to the freshly poured concrete. The structural adhesives include water insensitive thermal setting resins such as epoxy resins. These structural adhesives are well-known and the invention is not limited to epoxy resins alone. In each instance, the concrete includes suitable reinforcing, generally indicated at 13a and 13b. This can be provided as such in spaced relation to the pipe proper, as in FIG. 5, or can be attached as by spacers 14 to the pipe proper.

In the following, I have set forth the details of four different pipelines comparing the structure of the composite pipeline with that of the contemporary pipeline constructed in accordance with the usual practice heretofore. In each instance the pipe utilized was of the same yield strength.

CASE I

A gas pipeline, 30" in diameter and of a yield strength of 75,000 psi, operating at 1,000 psi to be located in 130 ft. of water.

    ______________________________________
    Contemporary      Composite
    Pipeline          Pipeline
    ______________________________________
    0.562" Wall       0.33" Wall
    2.6" of 140 lb. concrete
                      4" of 140 lb. concrete
    ______________________________________

    ______________________________________
    Contemporary      Composite
    Pipeline          Pipeline
    ______________________________________
    0.625" Wall       0.312" Wall
    2.8" of 190 lb. concrete
                      4.0" of 190 lb. concrete
    ______________________________________

    ______________________________________
    Contemporary      Composite
    Pipeline          Pipeline
    ______________________________________
    0.875" Wall       0.312" Wall
    5.4" of 165 lb. concrete
                      8.0" of 165 lb. concrete
    ______________________________________

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    ______________________________________
    Contemporary      Composite
    Pipeline          Pipeline
    ______________________________________
    0.438" Wall       0.312" Wall
    4.5" of 140 lb. concrete
                      4.8" of 140 lb. concrete
    ______________________________________