NO341783B1 - Flow hose connector - Google Patents

Abstract

A connector for connecting flow hose elements in a seismic tow comprising a cylindrical inner part and two interconnected opposite mirror-arranged cylindrical identical outer parts completely or partially enclosing around the inner part, each cylinder half of the cylindrical inner part having an outer surface of the floating member. the cylindrical inner part further has an inner end wall near one of the ends of the cylinder halves which blinds the cylinder and thus forms defined floating elements in each of the flow hose elements and a gas filling valve arranged in an opening a middle portion between the cylinder halves of the inner filling the outer parts have an inner surface with a corresponding raft structure for cooperating engagement, each with its own surface on the cylinder halves an outer wall diameter against at least the middle portion which allows to form a protective space for venti and to form a force sufficient to hold mounted equipment and to accommodate at least one upper and a lower through hole, in one embodiment there will preferably be several intermediate holes arranged in the circumference of the mirror-facing outer parts arranged in the outer part wall axis parallel to the longitudinal axis of the cylinder and further with a coupling bolt through each pair of the opposite the at least upper and lower holes in the two mirrored outer parts arranged to press the outer parts against each other and thus the inner part and the two outer parts against each other to hold flow hose elements between each end of the inner part and each of the outer parts and where the coupling bolts are also at the same time fastening bolts for connecting seismic-related equipment.

Description

Introduction

The invention relates to additional equipment for marine seismic tows. Specifically for a connection unit, connector, for elongated floating elements for a seismic tow.

Background and known technique

Known technology uses sockets as joints which usually include threads for screwing on outer locking sleeves or recesses for attaching hose clamps or similar strip tensioners around the hose. Pipes of large diameters are usually connected by welding or a flange connection.

Splicing elements for floating hoses usually use sleeves as splices with, hose clamps, steel bands and metal strips and mounted welded steel clamps for attaching and handling depth ropes to springs and lifting hooks. If additional equipment such as global positioning system (GPS), lights or other equipment is installed on the connectors, they must be extended and the hoses must be shortened accordingly to maintain the correct source distance.

Patent application US20020045989 A1 describes such a coupling with a sleeve for threading into fluid hoses and with a fluid filling valve. The surface of the sleeve is corrugated or with coarse barbs so that the coupling band or a clamp can hold well if the sleeve and the hose and the hoses do not slip off.

US patent US5144588 also shows a coupling for float hose elements where the sleeve has a one-way valve for pressurized air from one float hose to the next to keep the hose with attached equipment afloat. The sleeve has a corrugated surface to prevent slipping of the hose. The hose is held in place with the help of clamps, steel bands etc. Separate clamps are used around the sleeve to hold equipment that is to be installed.

Patent publication US20030226488 A1 describes a streamer cable connection. It has a cylindrical inner part for clinging to the cable which is to rotate freely inside an outer partially conical cylinder which is to be connected to suspension and flotation equipment. The external conical shape ensures less noise influence by the streamer cable.

Brief summary of the invention

The purpose of the attached invention is to provide a connection unit, connector, for connecting float hose elements in a seismic tow comprising

-a cylindrical inner part and two connected opposite mirror-image arranged cylindrical identical outer parts completely or partially surrounding the inner part,

- where each cylinder half of the cylindrical inner part

has an external surface with a surface structure for the arrangement of an associated float hose element, - and where the cylindrical inner part further has

- an internal end wall near one of the ends of the cylinder halves which blinds the cylinder and thus forms defined floating elements in each of the floating hose elements

- and a gas filling valve arranged in an opening in the middle part between the cylinder halves of the inner part for gas filling to the one float hose

-how much further the two mirrored identical outer parts have

- an internal surface with a corresponding surface structure for cooperative engagement with each surface on the cylinder halves

- an outer wall diameter towards at least the central part which allows to form a protective space for the valve and to form strength enough to hold attached equipment and to accommodate - at least an upper and a lower through hole, in an embodiment it will preferably be several intermediate holes arranged in the circumference of the mirrored outer parts arranged in the outer part wall axially parallel to the longitudinal axis of the cylinder and further with - a connecting bolt through each pair of the opposing at least upper and lower holes in the two mirrored outer parts arranged to press the outer parts against each other and thus the inner part and the two outer parts against each other to hold float hose elements firmly between each end of the inner part and each of the outer parts and where the connecting bolts are also at the same time fastening bolts for connecting seismic-related equipment.

In the description, the expression "connector" is also used for the required connection unit, an expression that is used within the subject area.

This coupling unit reduces the need for steel parts and production hours. Known technology uses hose clamps, steel bands and metal strips as fastening devices both for attaching the hose to the sleeve and for attaching the suspension or lifting hook. All these details will be replaced by the outer cones with coupling bolt. In addition, known technology has various connectors for attaching different equipment. If GPS, lights or other equipment is desired mounted on the connectors that are used today, these must be extended to make room for the mounting bracket and the hoses adapted accordingly.

The actual shape/profile of the connector and the fact that all the bolts and the gas valve are "hidden" reduce wear when launching and boarding.

In terms of logistics, it will also be advantageous as all the connectors in this version can be the same, and the end user can, if desired, change the GPS location without having to dismantle and replace hoses and connectors.

Short figure explanation

The attached figures show some embodiments of the claimed invention.

Fig. 1 shows the coupling unit (0) according to an embodiment of the invention connected together with two outer parts connected around an inner part and cut-off float hose elements in two different perspective views.

Fig. 2a is an end view of an embodiment of the same embodiment of the invention. Fig. 2b shows the section A-A from fig. 2a, i.e. the invention in side view and partially cut through so that suspension details in the lower coupling bolt are visible.

Fig. 2c shows detail B from Fig. 2b.

Fig. 2d is the section C-C from Fig. 2b and shows a suspension device for e.g. depth rope and valve for buoyancy gas

Fig. 2e shows detail D from Fig. 2d, the valve (15) for buoyancy gas

Fig. 3a shows a side view of an outer part (2) according to an embodiment of the invention

Fig. 3b shows the section F-F from Fig. 3a

Fig. 3c and 3d show the outer part (2) in two different perspective views, respectively from the outer back and inner front.

Fig. 4a shows a side view of the inner part (1) according to an embodiment of the invention where the surface structure of the surfaces is conical and evenly decreasing.

Fig. 4b shows the section E-E from Fig. 4a

Fig. 4c and 4d show the inner part (1) in different perspective views

Fig. 5 shows a perspective view of an embodiment of the invention connected together and with a fastening bracket in the upper position connected to the upper fastening bolt and two of the middle ones.

Fig. 6 shows a section of an embodiment of the invention corresponding to Fig. 2d but here with a bracket in the upper position connected with the 3 upper coupling bolts.

Fig. 7a shows a side view of an embodiment of the inner part (1) of the invention where the surfaces of the surface structure of the cylinder halves (102a, 102b) are conical and gradually tapering towards the ends (103a, 103b)

Fig. 7b shows the section G-G from fig. 7a

Fig. 7c-d shows the same design as Fig. 7a of the inner part (1) in different perspective views.

Fig. 8a shows a side view of an outer part (2) according to an embodiment of the invention in which the internal surface structure of the surfaces is conical and gradually tapering.

Fig. 8b shows the section F-F from Fig. 8a

Fig. 8c and 8d show the same design as Fig. 8a of the outer part (2) in two different perspective views, respectively from the outer back and inner front.

Embodiments of the invention

Implementation of the invention will subsequently be explained with reference to the attached figures.

The purpose of the attached invention is to provide a connection unit (0), connector, for connecting float hose elements (3) in a seismic tow comprising

- a cylindrical inner part (1) and two identical cylindrical outer parts (2a, 2b) for a mirror-facing device about the inner part (1),

- where each cylinder half (102a, 102b) of the cylindrical inner part (1) has an external surface with a surface structure for the arrangement of an associated float hose element (3),

- and where the cylindrical inner part (1) further has

- an internal end wall (110) close to one of the ends (103a, 103b) of the cylinder halves which blinds the cylinder and thus forms defined floating elements in each of the floating hose elements

- and a gas filling valve (15) arranged in an opening (104) a middle part (M) between the cylinder halves (102a, 102b) of the inner part (1) for gas filling to the one float hose

-how much further the two mirrored identical outer parts (2a, 2b) have

- an internal surface with a corresponding surface structure for cooperative engagement with each surface on the cylinder halves (102a, 102b)

- an outer wall diameter (TD) towards at least the middle part (M) which allows to form a protective space for the valve (15) and to form strength enough to hold attached equipment and to accommodate

- at least one upper and one lower through hole (20U, 20L), in one embodiment there will preferably be several intermediate holes (20M) arranged in the circumference of the mirrored outer parts arranged in the outer part wall axis parallel to the cylinder's longitudinal axis (A) and further with

- a coupling bolt (8) through each pair of the opposite at least the upper and lower holes (20U,20L) in the two mirrored outer parts (2a, 2b) arranged to press the outer parts against each other and thus the inner part (1) and the two outer parts (2a, 2b) against each other to hold float hose elements (3) firmly between each end of the inner part (1) and each of the outer parts (2a, 2b) and where the connecting bolts (8) are also fastening bolts for connecting seismic-related equipment.

The outer parts, which are basically identical, are assembled so that the holes form pairs so that coupling bolts can be passed through. When tightening the coupling bolts, the internally structured surfaces in the outer parts are pulled towards the hose and onto the corresponding structured surfaces on the inner part, ensuring a tight connection of the hose to the cone. The hose connection must work for a float hose for use in a seismic tow and as a suspension for the seismic sources. Typical diameters for such hoses are in the range of 12 to 24 inches. A connector's task according to the invention is to connect two hose elements (hence the name) and at the same time function as a suspension for the seismic sources via depth ropes and function as foundations for additional equipment, e.g. GPS. A connected embodiment of the invention is shown in Fig. 1, Fig. 2b and Fig. 5.

In one embodiment of the invention, the cylindrical inner part (1) has an outer, preferably but not necessarily uniformly decreasing, conical shape with decreasing circumference (O) towards each cylindrical end (103a, 103b) and the two mirror-image identical outer parts (2a, 2b) has an internal conical shape corresponding to the external conical shape of the cylinder halves (102a, 102b). Please refer to Fig. 4a-d and Fig. 3a-d.

In one embodiment of the invention, the inner part (1) has an outer tapering surface structure with a decreasing circumference (O) towards each cylinder end (103a, 103b) and each of the outer parts (2a, 2b) has an inner tapering surface structure corresponding to the outer tapering surface structure of the cylinder halves (102a, 102b). The transition between the steps is preferably chamfered to avoid sharp edges. Please see Fig. 7.

Common to the above-mentioned versions apply:

In an embodiment of the invention, the outer parts (2a, 2b) have increasing wall thickness (T) towards the middle part (M) to make room for the filling valve and to create enough strength to hold attached equipment in the coupling bolts (8). This in the form of an outer gradually increasing or conical shape.

The connectors essentially consist of three main components made of a light material, an inner part, double inner cone (cone sleeve), (1) with a through valve (15) for filling the hose with air (or other applicable gases), see fig2e. detail D, and the cone is further blinded towards the end/side (110), the inner cone is a cone at both ends and the two outer parts, two outer cones (2); one to each end of the inner part's inner cones (cylinder halves) (102a, 102b).

These components lock the hose ends (3) in place using a desired number of bolts and nuts (8) through the material of the cone (2a, 2b) in the longitudinal direction of the connected hose and hold the two outer parts, the outer cones, (2a,2b) together around the inner cone . The expansion of the hose over the increasing diameter of the cone exerts a spring force against the cones (102a, 102b) of the inner part and the force of the outer cones (2a,2b) on the hose together exerts the holding forces so that the hose is held in place in the joint, the connector. The conical surfaces make the coupling easy to assemble and to disassemble with little risk of damaging the float hose or coupling parts.

The very basic shape/profile of the connector and the fact that all the bolts and the gas valve are "hidden" reduce wear when launching and boarding. The conical external shape of the coupling element is preferably chamfered and rounded.

In terms of logistics, such connections will also be advantageous as all the connectors in this design can be the same, and the end user can, if desired, change the GPS location without having to dismantle and replace hoses and connectors. Moreover, the two outer cones will be the same and thus there are only 2 different parts to produce for the coupling unit itself.

Advantages of the invention are a simple, damage-free assembly/connection due to

pure conical elements and no sharp edges or threads at the same time that interaction in the outer and inner cones gives a good hold of the hose. Easy to produce and with enough strength in the massive outer cones to, among other things, attach coupling bolts and depth ropes for seismic equipment.

In one embodiment of the invention, the cylindrical inner part (1) has a recess (11) in the entire outer circumference of the cylinder wall (101). This will provide better space for connecting seismic-related equipment, a sleeve etc. which is placed on the coupling bolts and better room for the air filling valve. At the same time, material and thus the weight contribution to the overall system is reduced.

At the outer edges of the recess or at a corresponding distance from each other around the middle part, if a recess is not used, the inner part can have a raised stop edge for the outer parts, the outer cones, which can also serve as an additional clamp for the hose elements and ensure a centered connection and further hold of the hoses and that no one or both cones are pulled over the gas filling valve. See detail Fig. 2c.

In an embodiment of the invention, at least one distance element (D) is arranged between the two opposite outer parts, this can be a separate or made up of other equipment, see Fig. 2c, arranged between the outer parts (2a, 2b) to form an opening (G)(Gap) to at least the gas filling valve (15) and/or to provide clearance to pulleys etc.

In an embodiment of the coupling unit according to the invention, the coupling bolt (8) in the lower hole (20L) is arranged with a suspension device (6), such as a pulley, please see Fig. 2c, or other types of lifting equipment such as a shackle or hook between the outer wall and pulley between the outer parts (2a, 2b) for attaching depth ropes, suspension ropes etc. down to the connected seismic equipment. The coupling bolt (8) will act as a shaft for the suspension device (6). In addition, it will be possible to use the necessary spacer sleeves (7) on each side of the pulley and together with spacer sleeves this will form a spacer element (D). There is thus no need to fasten such a suspension device with additional locking devices such as hose clamps etc. which are fastened around the coupling unit.

According to an embodiment of the coupling unit according to the invention, the coupling bolt (8) in at least the upper holes (20U) is arranged with a mounting bracket (5) for necessary equipment, such as lifting equipment for loading and unloading the equipment, navigation and communication equipment, such as .ex. GPS. See Fig. 5 and 6. This will form a stable attachment to the floating unit. You therefore do not need a special coupling unit that is longer than the ordinary standard coupling unit in order to accommodate an extra bracket for the extra equipment. Source distance in the streamers can be maintained without having to shorten the flow hoses. One can therefore mount various equipment brackets and/or devices to handle the equipment between the opposite outer cones without affecting the length and source attachment distance. The weight of the equipment will also be reduced somewhat.

In one embodiment, this will also be attached to the bolts in the intermediate holes (20M) so that the bracket has a wider profile and basic structure and additional attachment points (several bolts) for increased holding strength and stability. In one embodiment, such brackets can also be attached in the lower positions with the center in the lower hole for further connection of equipment that will extend downwards into the water if the pulley system above is not to be connected.

The features in the above versions can be used in combination across each other. E.g. there is nothing in the way of the inner cone not having to have a central recess if the pulleys or the attached part can fit in the space around the bolt, i.e. is small enough or that the wall thickness of the outer part is thick enough.

In an alternative embodiment of the invention, inner parts/inner cones that are not blinded and do not have a gas filling valve can be used. Such a coupling unit can be used alternately with one of the other designs. This can provide a further advantage by saving the number of valves, but two types of inner parts must therefore be produced.

Claims (10)

Requirement 1. A coupling unit (0) for connecting float hose elements (3) in a seismic tow comprising -a cylindrical inner part (1) and a gas filling valve (15) and c a r a c t e r i s e r t w e d that the connection further comprises two identical cylindrical outer parts (2a, 2b) for a mirrored device about the inner part (1), - where each cylinder half (102a, 102b) of the cylindrical inner part (1) has an external surface with a surface structure for the arrangement of an associated float hose element (3), - and where the cylindrical inner part (1) further has - an internal end wall (110) near one of the cylinder halves' ends (103a, 103b) - and where the gas filling valve (15) is arranged in an opening (104) in the middle part (M) between the cylinder halves (102a, 102b) of the inner part (1) -how much wider the two mirrored identical outer parts (2a, 2b) have - an internal surface with corresponding surface structure for cooperative engagement with each surface on the cylinder halves (102a, 102b) - an outer wall diameter (TD) towards at least the middle part (M) which allows to form a protective space for the valve (15) and to accommodate - at least one upper and one lower through hole (20U, 20L) arranged in the outer part wall axis-parallel to the cylinder's longitudinal axis (A) and further with - a coupling bolt (8) through each pair of the opposite at least the upper and lower holes (20U,20L) in the two mirrored outer parts (2a, 2b) designed to press the outer parts against each other and thus the inner part (1) and the two outer parts (2a, 2b) against each other to hold float hose elements (3) firmly between each end of the inner part (1) and each of the outer parts (2a, 2b) and where the coupling bolts (8) are also attachment bolts for connecting seismic-related equipment. 2. The coupling unit according to claim 1, where the inner part (1) has an outer conical surface structure with decreasing circumference (O) towards each cylinder end (103a, 103b) and each of the outer parts (2a, 2b) has an inner conical surface structure corresponding to the the outer conical structure of the cylinder halves (102a, 102b). 3. The coupling unit according to claim 1 or 2, where the inner part (1) has an outer tapering surface structure with decreasing circumference (O) towards each cylinder end (103a, 103b) and each of the outer parts (2a, 2b) has an inner tapering surface structure corresponding to the external tapering surface structure of the cylinder halves (102a, 102b). 4. The coupling unit according to one of the preceding claims, where the outer parts (2a, 2b) have an increasing wall thickness (T) towards the middle part (M). 5. The coupling unit according to one of the preceding claims, where the cylindrical inner part has a recess (11) in the entire outer circumference of the cylinder wall (101). 6. The coupling unit according to one of the preceding claims, where the coupling bolt (8) in the lower hole (20L) is equipped with a suspension device (6) between the outer parts (2a, 2b) for attaching depth ropes. 7. The coupling unit according to one of the preceding claims where at least one spacer element (D) is arranged between the outer parts (2a, 2b) to form an opening (G) for at least the gas filling valve (15). 8. The coupling unit according to one of the preceding claims, where the outer part (2a, 2b) has a plurality of intermediate through holes (20M) between upper and lower holes. 9. The coupling unit according to one of the preceding claims, where the coupling bolt (8) in at least the upper holes (20U) is equipped with a mounting bracket (5) necessary equipment such as lifting equipment, navigation and communication equipment such as global positioning system (GPS ). 10. A method for connecting float hose elements (3) in a seismic tow comprising and c a r a c t e r i s e r t w e d to arrange a cylindrical inner part (1) with an outer surface with a surface structure on each cylinder half part (102a, 102b) inside each associated float hose element (3), - and where the cylindrical inner part (1) further has - an internal end wall (110) near one of the ends (103a, 103b) of the cylinder halves, which forms defined float elements with the corresponding float hose element - and a gas filling valve (15) arranged in an opening (104) in the middle part (M) between the cylinder halves (102a, 102b) of the inner part (1) for gas filling, a float hose and further arranged in two mirrored identical outer parts (2a, 2b) which have inside surface with a similar surface structure that the inner parts interlock with each other on the cylinder halves (102a, 102b), on the outside of the hose ends and around the cylinder halves (102a, 102b), arrange a coupling bolt (8) in at least one upper and one lower through hole (20U, 20L) in the outer part wall axially parallel to the longitudinal axis (A) of the cylinder through each pair of the opposite ones in at least the upper and lower holes (20U, 20L) in the the two mirrored outer parts (2a, 2b) and thus press the outer parts against each other and thus the inner part (1) and the two outer parts (2a, 2b) against each other so that the float hose elements (3) are held firmly between each end of the inner part (1) and each of the outer parts (2a, 2b) and where seismic-related equipment is also attached to at least the coupling bolt (8) in the lower hole (20L).