NO155075B - SEISMIC FLOYTE CONNECTOR WITH FLAT CONNECTORS. - Google Patents

Abstract

1. A seismic cable junction comprising a) a casing composed of - an external cylindrical sleeve (90) which houses - two separable internal bodies (10, 50) each having an end head (11, 51) with a right circular cross-section, defining one of the respective ends of the casing each end head having a axial through-bore (26), an extension (12, 52), solid with the said end head and which extends, from this end head, towards the interior of the casing generally to one side of an axial plane of the casing, towards the end head of the other internal body, each extension having transverse structures (15, 17; 55, 57) adapted to come into engagement with analogous transverse structures of the extension of the other internal body, and each extension defining an axial connection support opposite the other extension b) axial tie-rods (38, 78) fixed respectively to the end heads for transmitting traction to the seismic cable, c) at least one male connection and one female connection (110-113) respectively fixed on the connection supports, opposite each other, the said connections having respective, generally radial, electrical contact elements, which are connected to a bundle of electric conductors passing through the axial bores in the end heads, characterised by the fact that - the tie-rods (38, 78) are anchored in an axial drilling in the respective end heads (11, 51) of the internal bodies (10, 50), - one at least of the end heads having in addition a peripheral abutment (13) which delimits a radial support surface (14) extending towards the outside of the sleeve, - the sleeve (90) comprises at least one part (91) provided with an internal peripheral abutment delimiting a radial support surface (92) extending towards the inside of the sleeve and adapted to directly supports against the said peripheral abutment of the end head (11) of one of the internal bodies (10), and the said part (91) of the sleeve being in addition adapted to engage by threading with a portion (101) of the casing axially connected to the end head (51) of the other internal body (50) for axially acting on the end heads (11, 51) the one towards the other, and avoiding application of any constraint on the extensions (12, 52) and connections provided on these, when towing force is exerted on the cable by the tie-rods (38), - the cross-section of the axial through-bore (26) provided in each end head (11, 51) is such that it permits passage of the connections connected to the bundle of associated electrical conductors, without dismounting of the tie-rods.

Description

The invention relates to a joint for seismic cable, comprising the following parts: a) a capsule composed of an external cylindrical sleeve containing two separable internal bodies each having an end head with a circular cross-section and defining each end of the capsule, and each having a through axial bore, as well as an extension which is in fixed connection with the end head and from this extends towards the interior of the capsule and generally on one side of an axial plane to this and in the direction towards the end head on the other internal body, while each extension forms an axial connecting element carrier opposite the respective other extension, b) axial tension rods attached to each of the end heads to transmit tensile force to the seismic cable, c) at least one male and one female connecting element fixed opposite each other on the respective connecting elements -carriers, and which mostly have radial electrical contact elements which are connected to a bundle of ele ktric conductors that pass through the axial bores in the end heads.

More specifically, the invention relates to a coupling device which is intended to be used in connection with seismic cables to provide the necessary mechanical and electrical connections between the respective pulling cables or heating elements and wire bundles of the parts of the seismic cable to be connected.

It is known, with the help of a vessel, to tow a seismic cable which is composed of a large number of interconnected elements on which are distributed numerous interceptors which are referred to as hydrophones and are intended to intercept the acoustic waves that follow a tremor emitted of a seismic source. The information that is captured by the capture devices is transmitted by means of a cable with many conductors to a recording device placed on the vessel.

In order to connect the various cable elements to each other and to the vessel, cylindrical connection devices are generally used. The tensile elements for the two seismic cable members to be connected are attached to the ends of a rigid elongated box. This can often be in two parts that are joined together to provide the mechanical connection needed for towing the seismic cable. The electrical connection between the conductor bundles is formed with respectively male and female contact elements that are taken up inside the box, but the conductor bundles go through the end walls of the box. The box also accommodates the sleeve that is normally placed on each cable section to enclose the pulling elements and conductor bundles.

Until now, the connecting elements have been arranged radially

in the box. This device, which has served well, makes it possible for the traction force exerted on the traction elements to have little effect in the area of the coupling elements.

However, it has now been observed that this radial arrangement of the connecting means tends to limit the number of possible connections for a given diameter of the box. This means a corresponding limitation of the number of hydrophones that can be mounted in the cable, while the efforts are currently aimed at using many in order to obtain maximum information.

Incidentally, it is also difficult to intervene during use to repair a cable element. thus it is necessary not only to open the joint members, but also to detach the conductors from the connecting elements, since these cannot come out of the connecting member connected to the wire bundle. This latter cumbersome operation can rarely be carried out on board a vessel.

In practice, users are thus directed to replace the entire element, which leads to serious requirements for storage for each marine research project. This disadvantage naturally increases in importance with the number of interceptors and connections.

The present invention shall bring about a tangible improvement of this situation.

The purpose of the invention is to provide instructions for a form of joint or connection device whose connecting elements make it possible to connect a larger number of conductors (e.g.

for 200 collection devices).

Another purpose of the invention is to provide instructions

on a joint that is simple and robust and makes it easy to intervene to repair a cable element.

These purposes are achieved by a deed of the type mentioned at the outset, which is characterized by what appears from

the requirements.

Further features and advantages of the invention will be apparent from the following detailed description, where reference is made to the drawing, which illustrates a non-limiting embodiment example. Fig. 1 shows a longitudinal section of the joined connecting element, or joint. Fig. 2 shows a perspective view of one of the internal bodies.

Fig. 3 shows the joint in fig. 1 set from the left.

Fig. 4 shows a cross-section of the joint along the line IX-IX in fig. 1, and

fig. 5 shows a cross-section along the line X-X in fig. 1.

The joint according to the invention consists of two internal bodies 10 and 50 and a largely cylindrical sleeve 90. Each internal body has a head 11, resp. 51, at the end and extending axially into the joint to form two extensions 12 and 52 which are adapted to be anchored to each other as will be explained later.

The heads 11 and 51 on the internal bodies respectively

10 and 50 have on the circumference each a projecting projection 13, resp. 53, with outward-facing surfaces, intended to ensure cohesion of the joint body as will be explained later.

Each extension has at least one and preferably two transverse grooves 15, resp. 55, followed by a placement area 16, resp. 56, for connecting elements and finally at least one and preferably two, transverse protrusions 17 and 57 at the end of the extension. Each such projection 17, resp. 57, engages with the corresponding transverse track 15, resp. 55,

in the second extension.

Each extension has a largely hollow, half-cylindrical or -prismatic shape with a recess 18, resp. 58, in the area of the contact elements except in its middle part 19, resp: 59, where there are arranged bodies 44 to fix the two axial extensions 12 and 52 to each other radially.

These fastening means are designed as follows: one 12

of the axial carrier members is provided in its central part 19 with a threaded bore 20 for the insertion of a fixing screw 44.

The screw 44 is preferably threaded over half its length.

while the other half, which extends between the head of the screw and the threaded part, has a smaller diameter than the bore 20, so that the screw 44 can be brought into engagement. The second axially running carrier part 52 is likewise made in its middle part 59 with a threaded hole 60 to accommodate the screw 44 which passes through the threaded bore 20 in the first ■carrier part 12. A stop ring 42 is attached with a cotter pin 43 to the middle part of the fixing screw 44.

It will be understood that the anchoring of the two axial extensions 12 and 52 to each other is secured by means of the protrusions 17 and 57 which come into engagement with the respective corresponding grooves 15 and 55 in the second extension. They are held in an anchored position with the fixing screw 44 which engages in the threaded bore 20 in the axial support part, as a stop ring 42 is threaded onto the screw which is fixed with the pin 43, and which is tightened in the threads in the bore 60 in the axial support part 52.

When the screw 44 is loosened, the stop 42 prevents displacement of the screw 44 in relation to the axial support part 12. The two axial support parts 12 and 52 are thereby separated, and thus also the male and female contact elements of the connecting member.

Each of the extensions 12 and 52 is designed with two areas 21, 22, resp. 61, 62, for contact elements (110, 111,

112, 113, fig. 5). These contact areas 21, 22, and 61, 62

have installation (23,24) and attachment areas for the contact elements at the ends.

These contact elements 110, 111, 112 and 113 are attached

in the contact zones in the joint member's contact area by means of screws 25 inserted in threaded bores 46, 47, 48 and 49.

Each of the heads 11 and 51 on the internal bodies 10 and 50 respectively has three partially threaded bores 30, 31, and 32 evenly spaced around its axis 45, as well as a through axial recess 26. This through axial recess 26 is formed by a central bore 26 and three protrusions 27, 28, and 29 located between the three recesses 30, 31

and 32. Two of these bulges, 27 and 28, enable the two contact elements 110, 111, resp. 112 and 113, while the third protrusion 29 enables the passage of cables connected to them.

As shown in fig. 2 and 5, each extension 12, 52 is moreover, in the area adjacent to the heads of the internal bodies 11 and 51, formed with a bore 33 which opens into the through axial bore 26 and is intended to receive the conductor bundles.

Each head 11, 51 on the internal bodies 10, resp.

50, hbi furthermore an annular groove 35, resp. 75 on the circumference, intended to receive a ring gasket 34, resp. 74.

Each head 11 and 51 of the internal bodies 10 and 50 also has an external narrowed part 36, resp. 76, which with its female end has an annular thickening 46, resp.

86, and say designed with annular grooves 37, resp. 77, designed to receive under tension the tight sheaths on each of the two cable parts to be connected, the sleeve 90 extending far enough to cover the parts 36 and 76 as shown at 98 and 108..

It will be understood that each tensioning element 38 has an advanced head 39 which is introduced into one of the partially threaded bores 30, 31 or 32. The head 39 is held tight and blocked by a sleeve 41 fitted to the tensioning element 38 in the threads 40 of the bore.

The sleeve 90 is assembled from two parts 101 and 91 joined together using external and internal threads 97 respectively.

The end part of the threaded part 101 of the sleeve forms, with an axially inward-facing surface 102, a stop for the joint intended to bear against the outward-facing stop 54 on the internal body 50.

The internally threaded part 91 of the sleeve has an internal surface 92 which forms an inward-facing abutment for the joint member and bears against the outward-facing abutment 14 on the internal body 10.

It will thus be understood that the surfaces 102 and 92 during the jointing of the sleeve come into contact with the surfaces 54 and 14 on the heads of the internal bodies and thereby ensure the necessary mechanical stiffness of the joint and thus a mechanical connection between the respective tensile elements of the two cables -parts to be connected.

To regulate the buoyancy of the cables, they are filled with a light fluid, e.g. the kerosene, and it is therefore necessary to ensure that the joint is sealed.

During the aforementioned merger, the two parts 91 and

101 of the sleeve compress the ring gaskets 34 and 74 in the annular grooves 35 and 75 in the heads of the internal bodies to make the organ tight. This sealing is completed with two ring gaskets 93 and 94 which are placed in the annular grooves 95 and 96 in the sleeve's externally threaded part 101 and during joining are pressed together by the sleeve's internally threaded part 91.

The assembly of the joint is achieved with the following successive operations. The male and female contact elements 110, 111, resp. 113, associated with the respective conductor bundles are introduced through the recess 2 6 in the internal body as described above.

The connecting elements 110 and 111 on one of the cable elements to be connected are inserted into the protrusions 27 and 28,

and the bundle of corresponding conductors in the bulge 29. The same applies to the connection elements 112 and 113 on the other cable element to be connected. The contact elements 112 and 113 are then bent back 180° to avoid that the conductor bundles remain between the cooperating contact elements.

The conductor bundles are placed in the bore 33, and the contact elements are then fixed in their respective places with the help of the screws 25.

The tension elements are attached to the heads of the internal support members, and each of the tight sheaths is pulled in on

the grooved parts 3-6, resp. 76.

The two axial extensions 12 and 52 are anchored to each other as the transverse projections 17 and 57 are brought into engagement in the transverse grooves 15 and 55, and are then attached to each other with the screw 44 provided with the stop ring as described earlier.

The sleeve is then joined to provide the mechanical connection between the two cable elements to be connected, and sealing of the joint. The outer surface of the sleeve is designed with reliefs and preferably with recesses, designed to cooperate with tools that make it possible to regulate the tightening of the sleeve.

It will be understood that the removal of the sleeve is carried out correctly

and simply by performing the described operations in reverse order.

In general, it can be said that the invention is not limited

to the embodiment that has been described and shown, as it is possible from this to give instructions on other forms and methods of execution without therefore exceeding the scope of the invention. For example, it will be easy to adapt the described construction

tion to the case that the seismic cable has four tensile elements.

Claims (10)

1. Joint for seismic cable, comprising a) a capsule composed of - an outer cylindrical sleeve (90) containing two separable inner bodies (10, 50) each having an end head (11, 51) which has a circular cross-section and defines each end of the capsule, and each of which has a continuous axial bore (26), an extension (12, 52) which is in fixed connection with the end head and extends from this towards the interior of the capsule and generally on one side of an axial plane to this and in the direction towards the end head of the second internal body, at the same time that each extension forms an axial connecting element carrier opposite the respective other extension, b) axial tension rods (38, 78) attached to each of the end heads to transmit tensile force to the seismic cable, c) at least one male and one female connection element (110-113) which are fixed opposite each other on the respective connection element carriers, and which have generally radial electrical contact elements which are connected a bundle of electrical conductors that pass through the axial bores in the end heads, characterized in that the tension rods (38, 78) which are known per se are anchored in an axial bore in each end head (11, 51) on the internal bodies (10- 50), that the extension (12, 15) has transverse designs (15, 17; 55, 57) arranged to engage with corresponding transverse designs on the extension of the second internal body, that at least one of the end heads additionally has a circumferential stop (13) which limits a radial support surface (14) which extends towards the outside of the sleeve, that the sleeve (90) has at least one part (91) provided with an internal circumferential abutment which limits a radial support surface (92) which extends towards the inside of the sleeve and is suitable for supporting directly against the said circumferential abutment on the end head ( 11) at one of the internal bodies (10), that the said part (91) of the sleeve is also arranged to have threaded engagement with a part (101) of the capsule axially connected to the end head (51) of the second internal body (50), in order to act axially on the end heads (11, 51) in opposite directions and avoid exerting stress on the extensions (12, 52) and the connecting elements arranged on them when pulling force is exerted on the cable by the tie rods (38), and that the continuous axial bore (26) in each end head (11, 51) has such a cross-section that it allows passage of the connection elements which are connected to the bundle of connected electrical conductors, without dismantling the tension rods. 2. Deed as stated in claim 1, characterized by that each end head (11, 51) has a projecting circumferential abutment (13, 53) which limits a radial support surface (14, 54) which extends towards the outside of the sleeve, and that the outer sleeve (90) is in two parts (91, 101) which are arranged for thread engagement and each includes an inner circumferential abutment (92, 110) which limits a radial support surface which extends towards the inside of the sleeve to lie directly against the projecting circumferential stop (13, 53) on the respective end head (11, 51). 3. Deed as stated in claim 2, characterized in that between one and one (77) of the end heads on the internal bodies and the sleeve are inserted resp. O-rings (34, 74, 93, 94) between the sleeve (90) and one (101) of said parts of the capsule and between this part of the capsule (101) and the other head (51) to ensure that the joint becomes waterproof. 4. Splicing as specified in claim 1, 2 or 3, characterized in that the heads of the respective internal bodies are provided with necks (76) with annular grooves (77) designed to press on waterproof sheaths at each of the two parts of the cable to be joined, and that the sleeve has sufficient extent to cover the necks. 5. Deed as stated in one of the claims 1-4, characterized by that the heads of the internal bodies are provided with partially threaded blind holes at attachment points for each tension rod, that the end of each tension rod has a thickened head (39) followed by an externally threaded nipple (41), and that the threaded nipple, after engagement of the tension rod's head in its bore, ensures fixation by clamping the tension rod onto the head of the corresponding internal body. 6. Joint as stated in one of the claims 1-5, characterized in that each extension, which has a largely semi-cylindrical or semi-prismatic hollow shape and is toothed in the area of the connecting elements, is provided in a central part of the capsule with organs for mutual connection attachment of the two axial extensions, while their anchoring takes place at their ends. 7. Deed as stated in claim 6, characterized in that the radial fastening means on the two extensions are formed partly by a threaded bore (20) arranged in the middle part of the extensions and partly by a fastening screw (44) which engages radially in one of the extensions, and that a stop collar (42) attached to the center of the fixing screw prevents any longitudinal displacement of the screw in relation to the extension that occupies it, all so that the extensions are brought together and held together after tightening the screw in the other extension and separate when the screw is loosened . 8. Joint as stated in one of the claims 1-7, characterized in that each of the extensions determines at least two longitudinal and close to each other locations (21, 22 and 61, 62) for connecting elements, and.that it is provided with carrying and fastening zones (23, 24) for the extensions. 9. Joint as stated in one of the claims 1-8, characterized in that each end head has three tension rod attachments (30, 31, 32) evenly distributed around its axis, and that the continuous axial bore is formed by a central bore (26) and three protrusions located between the tension rod mounts, two of which (27, 28) allow the connection elements to pass through, while the third (29) allows the wires to pass through to which they are connected. 10. Splicing as specified in one of claims 1-9, characterized in that the respective tension rods of the two parts of the cable lie in pairs in line at the mutual anchoring of the two extensions.