Equipment for connection of subsea lines

Abstract

A subsea equipment includes two manifolds for fluid import and export from oil wells. The first and second manifolds are arranged in parallel and are interconnected by a jumper. The first manifold includes all equipment for field flow control, such as, for example, selection valves, actuators or robot for remote operations and mandrels for connection to the Christmas trees. The second manifold includes only block valves and mandrels for future interconnection or interconnection to the first manifold.

Claims

1. A system for connecting subsea lines comprising: a first manifold and a second manifold arranged in parallel for fluid import and export, wherein: said first manifold comprises a reduced number of components comprising a first header; six fluid import mandrels; six import block/selection valves for the first header; six import block/selection valves for a second header; only one first main pipe block valve; one first foundation; two subsea lines for a first flowline; one first line support point, one first subsea installation device, one first interconnection mandrel, wherein the first header, the six fluid import mandrels; the six import block/selection valves for the first header; the six import block/selection valves for the second header; the one first main pipe block valve, the subsea installation device, and the one first interconnection mandrel are positioned on the one first foundation, and said second manifold comprises the second header; only one second main pipe block valve; only one import block/selection valve; two subsea lines for a second flowline; one second foundation; one second interconnection mandrel; one second line support point; and one second subsea installation device, wherein the second header, the second main pipe block valve, the one import block/selection valve, the one second interconnection mandrel, and the one second subsea installation device are positioned on the one second foundation; and a connection element for directly interconnecting the first interconnection mandrel with the second interconnection mandrel; wherein the six fluid import mandrels, the six import block/selection valves for the first header, the six import block/selection valves for the second header, the one first main pipe block valve, the two subsea lines for the first flowline, and the one interconnection mandrel of the first manifold are interconnected according to their functions in the first manifold, and wherein the second header, the one second block valve for the second header, the one import block/selection valve, the two subsea lines for the second flowline, and the one second interconnection mandrel of the second manifold are interconnected according to their functions in the second manifold.

2. The system according to claim 1, wherein the first manifold and the second manifold are machined single-block manifolds.

3. The system according to claim 1, wherein the connection element is a spool or a jumper.

4. The system according to claim 1, wherein the respective first and second headers are flowlines.

5. The system according to claim 1, wherein the subsea lines for the first flowline and the second flowline are subsea pipelines.

Description

BRIEF DESCRIPTION OF THE FIGURES

(1) The present invention can be well understood from the accompanying illustrative drawings, which, in a schematic form and without limiting the invention, represent:

(2) FIG. 1—Typical conventional scheme of connection between manifold (dual header) for six wells and four PLETs (only 2 depicted);

(3) FIG. 2—Simplified diagram illustrating the connection between the manifold for six wells and subsea line or pipeline, according to the present invention;

(4) FIG. 3—Perspective view of the manifolds and the main components installed with the line (flowline) for more than one pipeline, according to the present invention.

DETAILED DESCRIPTION OF THE INVENTION

(5) The present invention, represented by FIGS. 2 and 3, consists of an subsea equipment for connection of subsea lines comprising two manifolds (1a) and (1b) arranged in parallel, that is, contrary to the inline arrangement of the dual headers manifolds of the art (shown in FIG. 1) and manifolds having multiple flowlines.

(6) FIG. 2 shows a simplified scheme of the present invention, wherein the subsea equipment is divided into two manifolds (1a) and (1b), which are interconnected by connection element (8). Said connection element (8) can be a spool or jumper. Manifold (1a) comprises six fluid import mandrels (2), six import block/selection valves (3) for the header (5a), six import block/selection valves (4) for the header (5b), one main passage/header (5a), one block valve (6a) for the header (5a), one interconnection mandrel (7a) and two subsea lines (20) and (21) for the flowline (A). These components are properly interconnected according to their functions in the manifold (1a) set.

(7) In turn, manifold (1b) comprises one main passage/header (5b), one block valve (6b) for the header (5b), one import block valve (10), one interconnection mandrel (7b) and two lines (22) and (23) for flowline (B). As can be seen, these components are also conveniently interconnected according to their functions in the set of the invention.

(8) FIG. 3 represents the perspective view of the equipment according to the present invention, wherein some of the elements, not shown in FIG. 2, can thus be displayed. Thus, the indicated references are the same for the corresponding components of FIG. 2, except when differently referenced.

(9) As can be seen, manifold (1a) inwardly comprises said header (5a) and branches for fluid flow (not referenced). Outwardly, said manifold (1a) comprises a line support point (25a), a subsea installation device (26a), and a foundation (24a).

(10) Manifold (1b) also inwardly comprises the header (5b) and branches for fluid flow (not referenced). Likewise, outwardly, said manifold (1b) contains a line support point (25b), subsea installation device (26b) and a foundation (24b).

(11) The interconnection mandrels (7a) and (7b) have the function of interconnecting the manifolds (1a) and (1b) through a connection element (8), which can be a jumper or spool. Said interconnection mandrels (7a) and (7b) also serve for future expansions of subsea equipment, if necessary.

(12) The equipment configuration according to the present invention, as illustrated in FIG. 2, allows a significant reduction of certain elements when compared to the equipment of the art illustrated in FIG. 1. The reduction of components such as, for example, the connection elements (15), which are used to connect manifolds and PLETs, block valves (17) and jumper connectors (16) consequently results in a reduction in the number of PLETs. Therefore, this configuration makes it possible to decrease potential leak points, in addition to decreasing the amount of equipment installed and substantially reducing the total cost of the system.

(13) It should also be noted that the manifolds (1a) and (1b) are preferably and advantageously produced through a single-block machining process.

(14) Furthermore, the equipment arrangement according to the present invention maintains the same functionality as the prior art equipment, but with more efficiency and significantly lower cost, due to the fact that it allows the use of a reduced number of assembled components and a lower total size, therefore, providing lower weight to the equipment and less time for its installation in the seabed.

(15) Thus, the effects and advantages provided by the subsea equipment, object of the present invention, are numerous and evident to a person skilled in the art, highlighting, among them, the following: removal of connection elements from the subsea equipment (jumper or spool), thereby reducing the number of required connectors and pipes; reduction in the number of valves in the equipment, since it eliminates the need for block valve in the main pipe (header); valve block withstanding greater efforts during line installation, reducing the function of the structure to the foundation only; there is no welded component exposed to high line stresses, increasing the equipment's reliability; reduction in the number of parts (valves, connectors, mandrels, pipes); block architecture allows the production of equipment to serve more wells with lower weight; and lower cost to control remote operations in systems having more than one pipeline (dual flowline, for example).