DE4319332C1 - Float body for pipelines - Google Patents

Abstract

A float body for pipelines, in particular of suction dredgers, comprises at least two plastic hollow bodies 1 which enclose the pipeline in the form of a sleeve and are held together by band-like clamping elements arranged in annular grooves 8 on the outer surface 5 of the hollow bodies. Furthermore, the outer surface 5 of the hollow bodies 1 is provided with axial grooves 7, which extend over the entire length of said hollow bodies. <IMAGE>

Description

The invention relates to a buoyancy body for pipe lines, especially of dredgers, of little at least two, enclosing the pipe in the form of a sleeve Hollow bodies made of plastic, which are band-shaped Clamping elements are held together in ring grooves arranged on the outer surface of the hollow body are.

When excavating to manufacture or deepen ship water or to extract gravel or sand  - insofar as the suction method is used - the part of the pipeline leading from the excavator to the bank Removal of the funded goods with such the DE-OS 20 04 007 known and ge with foam filled buoyancy floats made to a unrestricted change of location of the Enable excavators.

The disadvantage of these is not only the large material requirements for the foam filling. It is for environmental reasons protection also increasingly problematic because of these bodies to dispose of the foam part.

In U.S. Patent 4,764,137 there are further buoyancy bodies described from steel, which also with foam are filled. Apart from the disadvantages that the Stick to foam, steel bodies are heavy and corro susceptible to sions and are difficult to design in this way that the pipeline is half immersed and free can turn.

To avoid getting out of the foam filling  resulting problems are already buoyancy bodies sets whose hollow plastic body is only filled with air and hermetically sealed from the atmosphere are. These bodies face those with one Foam filling a much lower strength on, especially temperature fluctuations the environment significantly at the pressure of the trapped air from what at high ambient temperatures uncontrolled and undesirable bulges and dents at very low ambient temperatures the hollow body leads. This temperature dependent Ver formations with z. B. to counter metallic fixtures, also creates difficulties in disposal the hollow body. Therefore, between the outer and inner surface of the hollow body conical through breaks formed as a support element between these Surfaces work. In the area of these breakthroughs, however compliance with an indispensable for these hollow bodies constant wall thickness extremely difficult.

The object of the invention is now filled with air  Hollow bodies of buoyancy bodies for pipelines, especially of suction dredgers, with a large deformation resistance and their disposal facilitate.

This object is achieved on the basis of a Buoyancy body of the type described at the beginning solved in that in the outer surface of the Hollow bodies extending over their entire length, preferably wedge-shaped axial grooves are incorporated.

This according to the invention in the outer jacket of the Axial grooves molded into the hollow body give the hollow body not only sufficient stiffening, esp especially against those caused by temperature changes fluctuations in the pressure of the air filling. It enables also when using certain locks on the for the solid cohesion and seating of the hollow body the clamping tools are essential for the clamping tools in this area inside and outside the tension belts the start.  

In an expedient development of the invention is the inner surface of the hollow body with itself axial ribs extending over their entire length preferably with a rectangular cross section, ver to the axial grooves in the outer surface sets can be arranged. With these axial ribs, whose height during the manufacture of the hollow body easy replacement of parts on the inside diameter the main shape to the respective circumstances easily is to be adjusted, in addition to an increase in Verstei tion resistance of the hollow body essentially firm seating of the float on the tubes of the Guaranteed line, causing excessive Ver wear of the buoyancy body by rubbing against the Avoid pipes or by tipping if there is too much scope that will.

In another advantageous embodiment of the Erfin are the bottom surfaces of the ring grooves, of which one in the immediate vicinity of each end face of the Hollow body can be provided between the axial grooves designed as flat surfaces.  

These ring grooves, one of which is preferred in each hollow body three pieces are molded in, support the stiffening of the hollow body starting from the axial grooves per, so that possible slight deformations of the hollow body meaningless due to changes in internal air pressure are. If there is still a slight deformation the hollow body occurs, this is preferred by the Arrangement of an annular groove in the immediate vicinity of the End faces because of the great rigidity of these surfaces so far eliminated that a loosening of the preload band-shaped clamping elements made of textile Material is not possible. The arrangement of three Ring grooves also has the advantage that at Difficulty installing the float in the middle lere ring groove placed a usual mounting strap while the two are adjacent to the end faces take the final tightening straps into the ring grooves.

An embodiment of the invention will be added  Hand described in the drawings. They represent:

Fig. 1 The view of a hollow body formed as a half-shell of a buoyancy body.

Fig. 2 is a plan view of the half shell of FIG. 1.

Fig. 3 is a sectional view taken along the line AA through the half shell of FIG. 1.

The shown and as a half-shell of a buoyancy pers, which can be arranged around a delivery line of a suction excavator, not shown, formed hollow body 1 consists of polyethylene and has two end faces 2 and 3 and an inner 4 and outer 5 outer surface. In the inner lateral surface 4 , axial ribs 6 are formed which extend over the entire length of the hollow body 1 and with which the hollow body 1 or the buoyancy body formed from a plurality of hollow bodies 1 is supported on the delivery line.

V-shaped axial grooves 7 , which also extend over the entire length of the hollow body 1 , and annular grooves 8 are incorporated into the outer circumferential surface 5 of the hollow body 1 , offset from the axial ribs 6 . The bottom surfaces 9 of the annular grooves 8 , in which the tensioning straps (not shown) which serve to hold together the hollow body 1 which forms a buoyant body, are not curved in the region between the axial grooves 7 , but rather form flat surfaces, as a result of which the hollow body 1 forms a receive additional stiffening.

The hollow body 1 has on its bottom surfaces 10 projections 11 and depressions 12 which, when joining together hollow bodies 1 to form a buoyancy body, provide a toothing of the individual bodies with one another.

Claims (8)

1. buoyancy body for pipelines, in particular suction dredgers, which consists of at least two, the pipe sleeve-shaped enclosing hollow bodies made of plastic, which are held together by band-shaped clamping elements, which are net in ring grooves on the outer lateral surface of the hollow body, characterized in that in the outer lateral surface ( 5 ) of the hollow body ( 1 ) extending over their entire length axial grooves ( 7 ) are incorporated. 2. Buoyancy body according to claim 1, characterized in that the axial grooves ( 7 ) are wedge-shaped. 3. Buoyancy body according to claim 1 or 2, characterized in that the inner lateral surface ( 4 ) of the hollow body ( 1 ) is provided with axial ribs ( 6 ) extending over its entire length. 4. Buoyancy body according to claim 3, characterized in that the axial ribs ( 6 ) have a rectangular cross section. 5. Buoyancy body according to claim 2 and 4, characterized in that the axial grooves ( 7 ) and axial ribs ( 6 ) are arranged offset from one another. 6. Buoyancy body according to one of the preceding claims, characterized in that the bottom surfaces ( 9 ) of the annular grooves ( 8 ) between the axial grooves ( 7 ) extend as flat surfaces. 7. buoyancy body according to claim 6, characterized in that an annular groove ( 8 ) in the immediate vicinity of each end face ( 2 , 3 ) of the hollow body ( 1 ) is easily seen. 8. buoyancy body according to claim 6 or 7, characterized in that the hollow body ( 1 ) have three annular grooves ( 8 ).