Assembly for connecting two superconducting cables
Patent Information
- Authority / Receiving Office
- FR · FR
- Patent Type
- Patents
- Current Assignee / Owner
- NEXANS SA
- Filing Date
- 2024-02-06
- Publication Date
- 2026-06-12
Abstract
Description
Title of the invention: Connection assembly for two superconducting cables Technical field and technological background
[0001] The present invention relates to a connection assembly configured to connect two superconducting cables. The invention further relates to a superconducting cable installation comprising an assembly according to the invention.
[0002] The invention applies typically, but not exclusively, to superconducting cables intended for the transport of electrical energy, in particular to low voltage, or medium voltage (in particular from 6 to 45-60 kV) or high voltage (in particular greater than 60 kV, and possibly up to 400 kV for example) electrical connections, whether in direct or alternating current, in different fields such as those of aerial, underwater, terrestrial electricity transport, or even aeronautics, or rail transport.
[0003] In particular, superconducting cables make it possible to transport electric currents, particularly high intensity ones, with cable sections that are much smaller than those of conventional transport cables composed of resistive electrical conductors, while limiting electrical losses along the cable, particularly losses due to the Joule effect, since this phenomenon is non-existent in the superconducting state.
[0004] A so-called "cold dielectric" superconducting cable generally comprises a cable core comprising at least one central superconducting portion, a dielectric layer surrounding the superconducting portion, a screen surrounding said dielectric layer and which may be made up entirely or partly of superconductors. The superconducting cable further comprises a cryogenic enclosure or cryostat surrounding said cable core. The cryostat typically comprises two concentric envelopes, thermally insulated from each other by a vacuum level, for example 105 mbar. A cryogenic fluid contained inside the internal envelope of the cryostat cools the cable core, in particular through the dielectric layer, hence the designation "cold dielectric", until it reaches a temperature at which the superconductor is in a state of superconductivity. This temperature is for example of the order of - 200°C for so-called "high temperature" superconductors.We also know superconducting cables, called "hot dielectric" where the superconducting part is included in a hollow element, generally a tube, in which a cryogenic fluid circulates. The dielectric layer is applied in this case to this tube, which can be thermally insulated, hence the designation "dielectric". hot ".
[0005] Furthermore, to obtain a long transmission link (several kilometers or tens of kilometers), it is necessary to successively connect superconducting cables. Indeed, superconducting cables are manufactured in finished unit lengths, defined by their transport capacity on a drum. This unit length depends specifically on the cable design chosen but is usually between a few hundred meters and 1 to 2 kilometers. Each superconducting cable is generally installed in a conduit which opens into a junction pit in which the superconducting cable is connected with the following superconducting cable.
[0006] During cooling to reach the superconducting state, the cable core shrinks significantly. It is estimated that its length varies by approximately 0.3%. For example, a cable distance of 800 m results in a shrinkage of the cable core of up to 2.4 m.
[0007] A solution for managing the reduction in the length of the cable core during cooling of superconducting cables is known from patent application publication US 2019 / 0260194 A1. The document describes a compensation device comprising a cryogenic envelope of curved shape with a large radius of curvature. At room temperature, the cable core is located at the portion of the inner wall of the cryogenic envelope having the largest radius of curvature. During cooling, the cable core shrinks by moving towards the portion of the inner wall of the cryogenic envelope having the smallest radius of curvature. The advantage of this compensation device is that no external force is applied to the cable core. It moves by itself in a controlled space.
[0008] However, the integration of the compensation device requires additional space in superconducting cable systems. The longer the superconducting cable, the larger the required bending radius of the compensation device. In a transmission link comprising several superconducting cables connected to each other, the space requirement associated with the integration of the compensation device(s) is even more difficult to manage.
[0009] There is therefore a need to manage, with limited space requirements, the shrinkages due to the cooling necessary to obtain the superconducting state, in a transmission link comprising a plurality of superconducting cables connected in series. Summary of the invention
[0010] For this, the invention proposes a connection assembly configured to connect two superconducting cables so as to provide a transmission link, each superconducting cable comprising a cable core surrounded by a cryogenic envelope, said assembly comprising: a junction device comprising two connection ports, each connection port being configured to receive the cable core of a respective one of the two superconducting cables, and two compensation devices configured to absorb a variation in the length of the cable core of a respective one of said superconducting cables, caused by a variation in temperature for a transition to the superconducting state, each compensation device comprising an input end configured to receive the cable core and an output end connected to a respective one of said connection ports so as to deliver the cable core to the joining device.
[0011] By providing a compensation device on either side of the junction device, the shrinkage due to cooling to obtain the superconducting state is managed at the level of each cable. By associating the compensation devices and the junction device, these can be provided in the same space, which facilitates their integration into the superconducting cable system.
[0012] According to one embodiment, the connection ports of the junction device are located at opposite ends of the junction device.
[0013] According to one embodiment, the connection ports of the junction device are located at the same end of the junction device.
[0014] According to one embodiment, each compensation device comprises a coaxial inner tube and an outer tube between which vacuum insulation is provided, the inner tube being configured to receive the core of the respective superconducting cable and a cooling fluid intended to cool said core to a cooling temperature for a superconducting state; said inner and outer tubes having at least one curvature of an angle greater than or equal to 90°, and the dimensions of the inner and outer tubes being configured so that, in said curvature: at room temperature, the cable core is near a portion of the inner wall of the inner tube having the largest radius of curvature, and at cooling temperature, the cable core is near a portion of the inner wall of the inner tube having a smallest radius of curvature.
[0015] According to a variant, the curvatures of the compensation devices are housed in a space delimited by one side of the junction device and / or arranged so that their axes are parallel to each other.
[0016] According to a variant, the curvatures are located substantially opposite each other along a longitudinal direction of the joining device.
[0017] According to a variant, the axes of the curvatures are perpendicular or parallel to a common central transverse plane of the connection ports of the junction device.
[0018] According to a variant, the curvatures of the compensation devices are on either side of a median plane of the junction device; and the axes of the curvatures are parallel to a common transverse plane of the connection ports of the junction device.
[0019] According to a variant, one of said compensation devices has a curvature of 360°, which compensation device having an output end oriented towards the same side as the corresponding connection port of the junction device, said output end of said compensation device being connected to the respective port via a compensating element comprising a U-shape.
[0020] According to a variant, the curvatures of the compensation devices have angles of 180° and have an angular offset between them so as to allow the cables connected to the compensation devices to pass.
[0021] The invention further relates to a superconducting cable installation comprising at least one junction pit into which superconducting cables arrive, and at least one connection assembly according to the invention located in said junction pit so as to connect two of said superconducting cables.
[0022] According to one embodiment, the superconducting cable installation comprises a plurality of connection assemblies located in said junction pit so as to connect a respective pair of said superconducting cables.
[0023] According to a variant, the joining devices are aligned in the same longitudinal direction and the curvatures are opposite each other in said longitudinal direction, or in a direction perpendicular to said longitudinal direction.
[0024] According to one embodiment, the installation comprises at least two junction pits into which the superconducting cables arrive, each junction pit comprising at least one connection assembly so as to connect a respective pair of said superconducting cables, one of the cables of the pair passing through the other junction pit.
[0025] According to one embodiment, the superconducting cables connected to the at least one connection assembly comprise a first end connected to said connection assembly and a second end connected to a compensation device.
[0026] The invention also relates to a superconducting cable installation comprising a plurality of connection assemblies according to the invention, connecting in series a plurality of cables of a transmission link.
[0027] The invention also relates to a superconducting cable installation comprising at least one junction pit into which superconducting cables arrive, each superconducting cable comprising a cable core surrounded by a cryogenic envelope, and a plurality of connection assemblies located in said junction pit so as to connect a respective pair of said superconducting cables, each connection assembly comprising: • a junction device comprising two connection ports, each connection port being configured to receive the core of a respective cable of the pair of superconducting cables, and • at least one compensation device configured to absorb a variation in length of the core of a first cable of the pair of superconducting cables, caused by a variation in temperature for a transition to the superconducting state, the compensation device comprising an input end configured to receive the core of the first cable and an output end connected to one of said connection ports so as to deliver the core of the first cable to the junction device, the compensation device comprising a coaxial inner tube and an outer tube between which vacuum insulation is provided, the inner tube being configured to receive the core of the first superconducting cable and a cooling fluid intended to cool said core to a cooling temperature for a superconducting state, said inner and outer tubes having at least one curvature of an angle greater than or equal to 90, installation in which the axes of the curvatures of the compensation devices are parallel to each other.
[0028] The invention also relates to a connection assembly configured to connect two superconducting cables so as to provide a transmission link, each superconducting cable comprising a cable core surrounded by a cryogenic envelope, said assembly comprising: • a junction device comprising two connection ports, each connection port being configured to receive the cable core of a respective one of the two superconducting cables, and • at least one compensation device configured to absorb a variation in length of the core of a first cable of the pair of superconducting cables, caused by a variation in temperature for a transition to the superconducting state, the compensation device comprising an input end configured to receive the core of the first cable and an output end connected to one of said connection ports so as to deliver the core of the first cable to the junction device, the compensation device comprising an inner tube and a coaxial outer tube between which vacuum insulation is provided, the inner tube being configured to receive the core of the first superconducting cable and a cooling fluid intended to cool said core to a cooling temperature for a superconducting state, said inner and outer tubes having a curvature of an angle equal to 90°. Brief description of the figures
[0029] The description which follows with reference to the appended drawings, given as non-limiting examples, will make it clear what the invention consists of and how it can be implemented. In the appended figures:
[0030] [Fig. 1] schematically represents a view of a first example of a connection assembly;
[0031] [Fig.2] schematically represents a view of the first example of a connection assembly;
[0032] [Fig.3] schematically represents a view of the first example of a connection assembly;
[0033] [Fig.4] schematically represents an example of a junction device;
[0034] [Fig.5] schematically represents another example of a junction device;
[0035] [Fig.6] schematically represents an example of a compensation device;
[0036] [Fig.7] schematically represents an example of a compensation device;
[0037] [Fig.8] schematically represents an example of a compensation device;
[0038] [Fig.9] is an explanatory diagram of an example of a compensation device;
[0039] [Fig. 10] is an explanatory diagram of an example of a junction device;
[0040] [Fig. 11] schematically represents a view of a second example of a connection assembly;
[0041] [Fig. 12] schematically represents a view of the second example of a connection assembly;
[0042] [Fig. 13] schematically represents a view of the second example of a connection assembly;
[0043] [Fig. 14] schematically represents a view of a third example of a connection assembly;
[0044] [Fig. 15] schematically represents a view of the third example of a connection assembly;
[0045] [Fig. 16] schematically represents a view of a fourth example of a connection assembly;
[0046] [Fig. 17] schematically represents a view of the fourth example of a connection assembly;
[0047] [Fig. 18] schematically represents a view of a fifth example of a connection assembly;
[0048] [Fig. 19] schematically represents a view of the fifth example of a connection assembly;
[0049] [Fig.20] schematically represents a view of the fifth example of the set of connection;
[0050] [Fig.21] schematically represents a view of a sixth example of a set of connection;
[0051] [Fig.22] schematically represents a view of the sixth example of the set of connection;
[0052] [Fig.23] schematically represents a view of the sixth example of the set of connection;
[0053] [Fig.24] schematically represents a view of a seventh example of a set of connection;
[0054] [Fig.25] schematically represents a view of the seventh example of a set of connection;
[0055] [Fig.26] schematically represents a view of an eighth example of a set of connection;
[0056] [Fig.27] schematically represents a view of the eighth example of a set of connection;
[0057] [Fig.28] schematically represents a view of the eighth example of a set of connection;
[0058] [Fig.29] is an explanatory diagram of an example of a connection assembly;
[0059] [Fig.30] schematically represents a view of a ninth example of a connection assembly;
[0060] [Fig.31] schematically represents a view of the ninth example of a connection assembly;
[0061] [Fig.32] schematically represents a view of another example of a connection assembly;
[0062] [Fig.33] schematically represents a top view of an example of installation;
[0063] [Fig.34] schematically represents a side view of the example installation of [Fig.33];
[0064] [Fig.35] schematically represents a side view of an example of installation;
[0065] [Fig.36] schematically represents a top view of the installation example of [Fig.35];
[0066] [Fig.37] schematically represents a side view of an example of installation;
[0067] [Fig.38] schematically represents a top view of the installation example of [Fig.38];
[0068] [Fig.39] schematically represents a side view of an example of installation;
[0069] [Fig.40] schematically represents a top view of the installation example of [Fig.39]. Detailed description
[0070] A first example of a connection assembly 100 according to the invention is represented by [Fig.l] which presents a perspective view. According to the conventions of [Fig.l], [Fig.2] presents a side view and [Fig.3] a top view.
[0071] The connection assembly 100 makes it possible to connect two superconducting cables C1, C2 so as to create a transmission link. Each superconducting cable C1, C2 comprises a cable core surrounded by a cryogenic envelope Cri, Cr2. The transmission link notably allows the communication of information having as its support the signal transmitted by the cables C1, C2 which compose it. The signal transmitted by the cables C2, C2 is notably an electric current. The superconducting cables are in particular connected in series.
[0072] A joining device 50 makes it possible to join together the superconducting cables C1, C2. The joining device 50 comprises two connection ports P1, P2. A first connection port P1 receives the cable core of a first superconducting cable C1; a second connection port P2 receives the cable core of a second superconducting cable C2.
[0073] In particular, in the junction device 50, the cable cores of the superconducting cables C1, C2, in particular the superconducting parts, are electrically connected to each other. In particular, the junction device makes it possible to join the cryogenic envelopes of the superconducting cables C1, C2 together for continuity of the circulation of the cryogenic fluid.
[0074] The connection assembly comprises two compensation devices 22a, 22b which absorb the length variations of the cable cores caused by a temperature variation for a transition to the superconducting state. Each compensation device 22a, 22b comprises an input end Ee configured to receive the cable core and an output end Es connected to the respective connection port PI, P2 to deliver the cable core to the junction device 50.
[0075] Thus, the retraction linked to cooling for the transition to the superconducting state of the first cable C1 and the second cable C2 is managed in the immediate vicinity of the junction device 50. By providing the junction device 50 and the compensation devices 22a, 22b in a single assembly 100, their integration in a single space is allowed, which facilitates their integration in a system of superconducting cables.
[0076] In the first example of connection assembly 100, the connection ports PI, P2, of the junction device 50 are located at the same end of the junction device 50. [Fig. 4] schematically represents the compensation device 50 in which the cable cores of cables Cl, C2 are connected to the connection ports PI, P2.
[0077] In particular, respective ends of the cable cores come side by side in the junction device 50, to be joined so as to make an electrical connection. The junction device 50 may comprise a cryogenic envelope which makes it possible to cool the ends of the cable cores to a superconducting state. The cryogenic envelope of the junction device 50 is in particular connected to a cryogenic envelope of each compensation device 22a, 22b via the connection ports PI and P2, so as to make continuity of the cooling fluid.
[0078] However, the junction device may have a different configuration. [Fig. 5] schematically represents another junction device 60 in which the cable cores of the cables C1, C2 are connected to the connection ports P1, P2. The junction device 60 of FIG. 5 is identical to that illustrated in [Fig. 4], except that the connection ports P1, P2 of the junction device 60 are located at opposite ends of the junction device 60.
[0079] In particular, a longitudinal direction of the joining device 50, 60 is a direction in which the cable cores extend into the joining device from one end of the joining device 50, 60.
[0080] In particular, the compensation device 22a, 22b comprises a coaxial inner tube and an outer tube describing a 360° angle curvature. The compensation device 22a, 22b is for example illustrated in [Fig.6].
[0081] However, the compensation device may have a different angle, greater than or equal to 90°. The device may have an angle of 180° as for example illustrated in [Fig.7], or an angle of 90° as for example illustrated in [Fig.8]. In particular, the compensation device is as described in the patent application publication US 2019 / 0260194 AL
[0082] [Fig.9] shows an example of a compensation device 24 having a 180° angle curvature. The compensation device 24 comprises a coaxial inner tube 8 and an outer tube 7. In a manner known per se, vacuum insulation is provided between the inner tube 8 and the outer tube 7. The inner tube 8 receives the core SK of the superconducting cable. A cooling fluid circulates in the inner tube 8 to cool the core SK to a cooling temperature for a superconducting state.
[0083] The dimensions of the inner 8 and outer 7 tubes are configured so that, at room temperature, the cable core SK is close to a portion of the inner wall of the inner tube 8 having the largest radius of curvature Ra; and at cooling temperature, the cable core SK is close to a portion of the inner wall of the inner tube Ri having a smallest radius of curvature. In particular, the internal diameter of the inner tube 8 is large enough to allow this movement of the SK cable core.
[0084] The compensation device 24 may comprise a rectilinear portion at one end of the curvature, such as for example at the right end in [Fig.9]. The end of the rectilinear portion then forms the end of the compensation device, in particular the output end Es. Alternatively, one end of the curvature of the compensation device 24 may come directly against the counterpart (superconducting cable C1 or connection port P1), such as for example at the left end in [Fig.9]. The end of the curvature then forms the end of the compensation device, in particular the input end Ee.
[0085] In particular, the angle of curvature is the angle traveled by the radius of curvature from the start of the curvature to the end of the curvature.
[0086] In particular, at one of their ends, the tubes 7, 8 connect to the cryogenic envelope Cri of the cable CL. In particular, the inner tube 8 is secured to an inner tube 5 of the cryogenic envelope Cri of the cable Cl; and the outer tube 7 is secured to an outer tube 4 of the cryogenic envelope Cri of the cable CL. Similarly, at the other end, the tubes 7, 8 can connect to a cryogenic envelope of the junction device.
[0087] Referring again to Figures 1 to 3, in the connection assembly 100, the bends are in particular housed in a space delimited by one side of the junction device 50, in particular a longitudinal side of the junction device 50. The space is in particular delimited by a plane tangent to the longitudinal side of the junction device 50, materialized in [Fig. 3] by a straight line A. Thanks to this arrangement, the size of the connection assembly is limited, in particular in a direction perpendicular to the plane tangent to the side of the junction device 50.
[0088] The curvatures of the compensation devices 22a, 22b are in particular arranged so that their axes [3 are parallel to each other. In particular, the axis of a curvature corresponds to the straight line containing the center of the radius of curvature around which the curvature extends. Thus, the size of the compensation devices 22a, 22b is reduced.
[0089] In particular, the curvatures of the compensation devices 22a, 22b are located opposite each other along the longitudinal direction of the junction device 50, which makes it possible to further limit the size of the connection assembly 100.
[0090] In particular, the first compensation device 22a has a 360° angle curvature and its output end Es is oriented towards the same side as the first connection port PI to which the core of the first cable Cl is connected. The connection assembly 100 comprises a U-shaped compensation element 15 which makes it possible to connect the output end Es of the first connection device 22a to the first port connection port PI. The compensation element 15 may also comprise a rectilinear portion between the output end Es and the U-shaped portion. This rectilinear portion makes it possible in particular to ensure that the U-shaped portion is located at a position along the longitudinal direction a which allows a connection with the first connection port PL. The compensation device 15 is particularly advantageous in a superconducting cable installation in which the superconducting cables C1, C2 arrive in a junction pit F from two opposite sides of the pit F. The compensation element 15 comprises in particular a cryogenic envelope in connection with the cryogenic envelopes of the first compensation device 22a and of the junction device 50, the cryogenic envelope of the compensation element 15 receiving the core of the first cable CL
[0091] [Fig. 10] represents a schematic view of the compensation device 50 in a cross-section, that is to say in particular in a plane perpendicular to the longitudinal direction of the compensation device 50. A central transverse plane is in particular a plane comprising a longitudinal direction of the compensation device 50 and separating a connection port PI, P2 into two equal parts. The central transverse plane common to the two connection ports PI, P2 is in particular represented by the straight line a. In particular, during the installation of the connection assembly 100, the junction device 50 is mounted so that the central transverse plane a is horizontal. This facilitates the operations of mounting the cable cores in the connection ports PI, P2 and their mutual connection within the junction device 50.
[0092] In particular, the axes of the curvatures of the compensation devices 22a, 22b are perpendicular to the common central transverse plane a of the connection ports PI, P2 of the junction device 50. In particular, by having their axes perpendicular to the common central transverse plane a of the two connection ports PI, P2, the curvatures of the compensation devices 22a, 22b extend mainly along the horizontal and have a limited size along the vertical. This arrangement is particularly suitable when the connection assembly 100 is installed in a junction pit F whose dimensions are more constrained in depth than in width. The connection assembly 100 is preferably arranged so that the longitudinal direction of the junction device 50 is parallel to the direction of arrival of the cables C1, C2.
[0093] [Fig. 11] illustrates a perspective view of a second example 120 of a connection assembly. Following the conventions of [Fig. 11], [Fig. 12] presents a side view and [Fig. 13] a top view.
[0094] The second example 120 of a connection assembly is identical to the first example 110, except that the curvatures of the compensation devices 22a, 22b are on either side of a median plane of the junction device 50 and that the axes [3 curvatures are parallel to the common central transverse plane a of the connection ports PI, P2 of the junction device 50. In particular, by having their axes parallel to the common central transverse plane a of the two connection ports PI, P2, the curvatures of the compensation devices 22a, 22b extend mainly along the vertical and have a limited space requirement along the horizontal. This arrangement is particularly suitable when the connection assembly 120 is installed in a junction pit F whose dimensions are more constrained in width than in depth. The connection assembly 120 is preferably arranged so that the longitudinal direction of the junction device 50 is parallel to the direction of arrival of the cables C1, C2.
[0095] [Fig. 14] illustrates a perspective view of a third example 130 of a connection assembly. According to the conventions of [Fig. 14], [Fig. 15] presents a top view thereof. The third example 130 of a connection assembly is identical to the first example 100, except that it comprises two compensation devices 26a, 26b having an angle of 90°. In particular, the curvatures of the compensation devices 26a, 26b are located substantially opposite each other along a direction perpendicular to the longitudinal direction of the junction device 50.
[0096] This arrangement is particularly suitable when the connection assembly 130 is installed in a junction pit F in which the superconducting cables C1, C2 arrive in the pit F at opposite sides of the pit F, and where the junction pit has fewer space constraints in a direction perpendicular to the direction of arrival of the cables C1, C2. The connection assembly 130 is preferably arranged so that the longitudinal direction of the junction device 50 is perpendicular to the direction of arrival of the cables C1, C2.
[0097] [Fig. 16] illustrates a perspective view of a fourth example 140 of a connection assembly. Following the conventions of [Fig. 16], [Fig. 17] shows a top view thereof. The fourth example 140 of a connection assembly is identical to the third example 130, except that it includes a first compensation device 24a having an angle of 180° and a second compensation device 26b having an angle of 90°.
[0098] This arrangement is particularly suitable when the connection assembly 140 is installed in a junction pit F in which the superconducting cables C1, C2 arrive at contiguous sides of the pit F, in particular when the cables arrive with a non-negligible angle between them, in particular 90°. The connection assembly 140 is preferably arranged so that the longitudinal direction of the junction device 50 is parallel to the direction of arrival of the first cable C1 which is connected to the first compensation device 24a.
[0099] A fifth example of a connection assembly 150 according to the invention is shown by [Fig. 18] which presents a perspective view. Following the conventions of [Fig. 18], [Fig. 19] presents a side view and [Fig.20] a top view.
[0100] The connection assembly 150 makes it possible to connect two superconducting cables C1, C2 so as to create a transmission link, already described in relation to the first example 100. The cables C1, C2 are identical to those described in relation to the first example 100.
[0101] In this fifth example of connection assembly 150, the connection ports P1, P2, of the junction device 60 are located at opposite ends of the junction device. The junction device 60 is in particular as described previously in relation to [Fig.5].
[0102] The connection assembly 150 comprises two compensation devices 22a, 22b which absorb the variations in length of the cable cores caused by a variation in temperature for a transition to the superconducting state. In particular, the compensation devices 22a, 22b each have an angle of 360°. In particular, the compensation devices 22a, 22b are as described previously in relation to [Fig. 6]. The compensation devices may however have different angles, for example as described in the first example of connection assembly 100.
[0103] The curvatures of the compensation devices 22a, 22b are in particular housed in a space delimited by one side of the junction device 60, in particular a longitudinal side of the junction device 60. The space is in particular delimited by a plane tangent to the longitudinal side of the junction device 60, materialized in [Fig.20] by the straight line A. Thanks to this arrangement, the size of the connection assembly is limited, in particular in a direction perpendicular to the plane tangent to the side of the junction device 60.
[0104] In particular, the curvatures of the space-saving devices 22a, 22b are located opposite each other along the longitudinal direction of the junction device 60, which makes it possible to further limit the space requirement of the connection assembly 150.
[0105] In particular, the axes of the curvatures of the compensation devices 22a, 22b are perpendicular to the common central transverse plane a (already described in relation to [Fig. 10]) of the connection ports P1, P2 of the junction device 60. The connection assembly 150 is preferably arranged so that the longitudinal direction of the junction device 60 is parallel to the direction of arrival of the cables C1, C2.
[0106] [Fig.21] illustrates a perspective view of a sixth example 160 of a connection assembly. Following the conventions of [Fig.21], [Fig.22] presents a side view and [Fig.23] a top view.
[0107] The sixth example 160 of connection assembly is identical to the fifth example 150 except that the axes [3 of the curvatures of the compensation devices 22a, 22b are parallel to the common transverse plane a of the connection ports PI, P2 of the junction device 60. In particular, by having their axes parallel to the central transverse plane a common to the two connection ports PI, P2, the curvatures of the compensation devices 22a, 22b extend mainly along the vertical and have a limited footprint along the horizontal. The connection assembly 160 is preferably arranged so that the longitudinal direction of the junction device 60 is parallel to the direction of arrival of the cables C1, C2. A platform P can be mounted in the pit F receiving the connection assembly 160 to allow operators to access the junction device 60 to make the junction between the cables C1, C2.
[0108] [Fig. 24] illustrates a perspective view of a seventh example 170 of a connection assembly. Following the conventions of [Fig. 24], [Fig. 25] presents a top view thereof. The seventh example 140 of a connection assembly is identical to the fifth example 150, except that it comprises a first compensation device 22a having an angle of 360° and a second compensation device 26b having an angle of 90°.
[0109] This arrangement is particularly suitable when the connection assembly 170 is installed in a junction pit F in which the superconducting cables C1, C2 arrive at contiguous sides of the pit F, in particular when the cables arrive with a non-negligible angle between them, in particular 90°. The connection assembly 170 is preferably arranged so that the longitudinal direction of the junction device 60 is parallel to the direction of arrival of the first cable C1 which is connected to the first compensation device 22a.
[0110] [Fig.26] illustrates a perspective view of an eighth example 180 of a connection assembly. Following the conventions of [Fig.26], [Fig.27] presents a side view and [Fig.28] a top view. [Fig.29] represents a schematic sectional view of the connection assembly 180.
[0111] The eighth example 180 of a connection assembly is identical to the fifth example 150, except that it comprises a first compensation device 24a having an angle of 180° and a second compensation device 24b having an angle of 180° which are opposite each other along the longitudinal direction of the junction device 60. The curvatures of the compensation devices 24a, 24b have a small angular offset ❖ between them so as to allow the cables C1, C2 connected to the compensation devices 24a, 24b to pass. In particular, the angular offset ❖ is a radian measured relative to the longitudinal direction of the junction device 60. Thus, the size of the connection assembly 180 is limited while allowing a connection of the cables C1, C2 to their respective compensation device 24a, 24b. In particular, the angular offset ❖ is a function of the diameter of the cables Cl, C2 or the diameter of the tubes of the compensation device.In particular he . is between a few degrees, for example 1°, and 45°, or even between 5° and 20°.
[0112] In particular, as illustrated in [Fig.29], the common central transverse plane a of the connection ports P1, P2 of the junction device 60 crosses the angular offset ❖ between the compensation devices 24a, 24b. Thus, when the connection assembly 180 is mounted in the pit F so that the common transverse plane a is horizontal, the curvatures of the compensation devices 24a, 24b extend mainly along the horizontal and have a limited footprint along the vertical.
[0113] This arrangement is particularly suitable when the connection assembly 180 is installed in a junction pit F whose dimensions are more constrained in depth than in width. This arrangement is furthermore particularly suitable when the connection assembly 180 is installed in a junction pit F in which the superconducting cables C1, C2 arrive at opposite sides of the pit F. The connection assembly 100 is preferably arranged so that the longitudinal direction of the junction device 60 is parallel to the direction of arrival of the cables C1, C2.
[0114] In particular, the connection assembly according to the invention is modular. The junction devices 50, 60 can be combined with any two of the compensation devices 22, 24, 26 having any angle greater than or equal to 90°, in particular as described previously. Thus, the connection assembly adapts best to the space available in the junction pit F and / or to the directions of arrival of the cables C1, C2 in the junction pit F.
[0115] In particular, the junction pit F defines a space in which the superconducting cables C1, C2 are joined, in particular by operators. The junction pit F may be delimited by walls, in particular laterally, at its base or at its top. The cables C1, C2 are in particular routed in conduits which open into the junction pit F.
[0116] In one embodiment of the examples described above, the cables C1, C2 have a first end connected to the respective compensation device of the connection assembly 100, 120, 130, 140, 150, 160, 170, 180 and a second end connected to another compensation device, in particular part of another connection assembly or being connected to a transmission link termination. Thus, for each cable C1, C2 the retraction due to cooling is managed at each of the ends of the cables. In doing so, the length to be managed by each compensation device is half as small compared to an example where, for each cable, a single compensation device would manage the retraction at one end of the cable. By managing the compensation at each end of the cables C1, C2, the compensation devices are relatively smaller.
[0117] Thus, a superconducting cable installation may comprise several of the previously described connection assemblies, for connecting in series a plurality of cables of a transmission link. A cable connected to two successive connection assemblies then has its first end connected to a compensation device of the first connection assembly and its second end connected to a compensation device of the second connection assembly.
[0118] The examples 100, 120, 130, 140, 150, 160, 170, 180 of connection assembly previously described comprise two compensation devices. However, another connection assembly could comprise a single compensation device. In particular, the compensation device is connected to the first connection port PI. The second cable C2 is connected, in particular directly, to the second connection port P2. In particular, such a connection assembly is otherwise similar to the examples of connection assembly previously described, in particular with regard to the connection device and the junction device. The axis of the curvature of the compensation device may be parallel or perpendicular to the common transverse plane a of the connection ports PI, P2 of the junction device 50, 60.
[0119] Figures 30 and 31 illustrate an example 190 of such a connection assembly. The connection assembly 190 comprises a compensation device 26 having an angle of 90°, previously described in relation to [Fig. 8], which connects to one end of a joining device 60 previously described in relation to [Fig. 5]. A cable C2 connects to the opposite end of the joining device 60. The assembly 190 is in particular received in a pit F. This example 190 of a connection assembly is particularly suitable for joining a cable C1 descending from a height, for example a bridge, to connect to a cable C2, for example on the ground.
[0120] [Fig. 32] illustrates an example 191 of a connection assembly identical to the example 190 previously described, except for the orientation in which it is installed in the superconducting cable system C1, C2. Indeed, this example 191 of a connection assembly is adapted to join a cable C1 rising from a low height, for example the ground, to a higher height, for example a bridge, to connect to a cable C2 located at the higher height.
[0121] A junction pit may comprise several connection assemblies as described above. This is particularly the case when several pairs of cables arrive in pit F to be connected by respective connection assemblies. For example, for a direct current system, one cable is at positive potential, another is at negative potential. The two cables arrive in pit F to be joined to their counterparts via two connection assemblies. In another example of a three-phase alternating current system, each phase is transmitted by a respective cable. The three phases arrive in pit F to be connected to their counterparts via three connection assemblies.
[0122] Preferably, the curvatures of the compensation devices have axes parallel to each other to limit the space taken up in the junction pit F, as for example illustrated in the figures.
[0123] Examples of installations comprising several connection assemblies will be described with reference to figures 33 to 40.
[0124] Preferably, to limit the bulk, the joining devices are all aligned in the same longitudinal direction. In particular, the transverse planes common to the joining devices are parallel to each other.
[0125] Preferably, the axes of the curvatures of the compensation devices are parallel to the common transverse plane of the connection ports PI, P2 of the connection devices.
[0126] Preferably, the curvatures of at least a portion of the compensation devices are opposite each other in the longitudinal direction common to the junction devices, as for example illustrated in Figures 33 to 36.
[0127] Preferably, the curvatures of at least a portion of the compensation devices are opposite each other in a direction perpendicular to the longitudinal common to the junction devices, as for example illustrated in Figures 35 and 36.
[0128] Preferably, the curvatures of at least part of the compensation devices are opposite each other so that their axes coincide, as for example illustrated in figures 37 and 38.
[0129] The different configurations of the connection assemblies or superconducting cable installations aim in particular to reduce or limit the length of the junction pit F.
[0130] As for example illustrated in figures 39, 40, the installation of superconducting cables comprising several connection assemblies may comprise at least two junction pits F in which the superconducting cables arrive. Each junction pit F comprises respective connection assemblies. Each connection assembly connects a respective pair of the superconducting cables arriving in the pit F, one of the cables of the pair passing through the other junction pit. Such an installation is particularly suitable when the number of superconducting cables is too high to connect them in the same space.
[0131] Figures 33 to 40 show installations in which the junction pits F comprise connection assemblies having a single compensation device. However, the examples shown could include connection assemblies comprising two compensation devices, as previously described. Furthermore, these figures show installations comprising 360° angle compensation devices, but the examples shown could include other compensation devices, in particular as previously described. On the other hand, in these figures 33 to 40, the connection devices have their connection ports located at their opposite ends. However, the joining devices could be different, and in particular include connection ports located at the same end of the joining device, in particular as previously described.
Claims
Claims
1. Connection assembly (100, 120, 130, 140, 150, 160, 170, 180) configured to connect two superconducting cables (Cl, C2) so as to provide a transmission link, each superconducting cable (Cl, C2) comprising a cable core surrounded by a cryogenic envelope (Cri, Cr2), said assembly comprising: a junction device (50, 60) comprising two connection ports (PI, P2), each connection port being configured to receive the cable core of a respective one of the two superconducting cables (Cl, C2), and two compensation devices (22, 24, 26) configured to absorb a variation in length of the cable core of a respective one of said superconducting cables (Cl, C2), caused by a variation in temperature for a transition to the superconducting state, each compensation device (22, 24,26) comprising an input end (Ee) configured to receive the cable core and an output end (Es) connected to a respective one of said connection ports (PI, P2) so as to deliver the cable core to the junction device (50, 60).,
2. A connection assembly (150, 160, 170, 180) according to claim 1, wherein the connection ports (PI, P2) of the junction device (60) are located at opposite ends of the junction device (60).
3. Connection assembly (100, 120, 130, 140) according to claim 1, wherein the connection ports (PI, P2) of the junction device are located at the same end of the junction device (50).
4. A connection assembly (100, 120, 130, 140, 150, 160, 170, 180) according to one of the preceding claims, wherein each compensation device (22, 24, 26) comprises: - a coaxial inner tube (8) and an outer tube (7) between which vacuum insulation is provided, the inner tube (8) being configured to receive the core of the respective superconducting cable and a cooling fluid for cooling said core to a cooling temperature for a superconducting state; said inner and outer tubes (7, 8) having at least one curvature of an angle greater than or equal to 90°, and the dimensions of the inner and outer tubes (7, 8) being configured so that, in said curvature: - at room temperature, the cable core is close to a portion of the inner wall of the inner tube (8) having the largest radius of curvature (Ra), and - at cooling temperature, the cable core is close to a portion of the inner wall of the inner tube (8) having the smallest radius of curvature (Ri).
5. Connection assembly (100, 120, 130, 140, 150, 160, 170, 180) according to the preceding claim, in which the curvatures of the compensation devices (22, 24, 26) are housed in a space delimited by one side of the junction device (50, 60) and / or arranged so that their axes ([3) are parallel to each other.
6. A connection assembly (100, 120, 130, 140, 150, 160, 170, 180) according to claim 4 or 5, wherein the bends are located substantially opposite each other along a longitudinal direction of the joining device (50, 60).
7. Connection assembly (100, 120, 130, 140, 150, 160, 170, 180) according to one of claims 4 to 6, in which the axes (P) of the curvatures are perpendicular or parallel to a common central transverse plane (a) of the connection ports (PI, P2) of the junction device (50, 60).
8. Connection assembly (120) according to one of claims 3 to 5, in which the curvatures of the compensation devices (22a, 22b) are on either side of a median plane of the junction device (50); and the axes (P) of the curvatures are parallel to a common transverse plane (a) of the connection ports (PI, P2) of the junction device (50).
9. Connection assembly (120) according to one of claims 4 to 8, wherein one (22a) of said compensation devices has a curvature of 360°, which compensation device (22a) having an output end (Es) oriented towards the same side as the corresponding connection port (PI) of the junction device (50), said output end (Es) of said compensation device (22a) being connected to the respective port (PI) via a compensating element (15) comprising a U-shape.
10. A connection assembly (180) according to claims 2, 4 and 6 wherein the curvatures of the compensation devices (24a, 24b) have angles of 180° and have between them an angular offset (❖) so as to allow the cables (Cl, C2) connected to the compensation devices (24a, 24b) to pass.
11. Installation of superconducting cables comprising: at least one junction pit (F) into which superconducting cables (Cl, C2) arrive, and at least one connection assembly according to one of the preceding claims located in said junction pit (F) so as to connect two of said superconducting cables.
12. A superconducting cable installation according to claim 11, comprising a plurality of connection assemblies located in said junction pit (F) so as to connect a respective pair of said superconducting cables.
13. Installation according to claim 12, in which the joining devices are aligned in the same longitudinal direction and the curvatures are opposite each other in said longitudinal direction, or in a direction perpendicular to said longitudinal direction.
14. Installation according to one of claims 11 to 13 comprising at least two junction pits (F) in which the superconducting cables arrive, each junction pit (F) comprising at least one connection assembly so as to connect a respective pair of said superconducting cables, one of the cables of the pair passing through the other junction pit (F).
15. Installation according to one of claims 11 to 14, in which the superconducting cables connected to the at least one connection assembly comprise a first end connected to said connection assembly and a second end connected to a compensation device.
16. A superconducting cable installation comprising a plurality of connection assemblies according to one of claims 1 to 10, connecting in series a plurality of cables of a transmission link.
17. Superconducting cable installation comprising at least one junction pit (F) into which superconducting cables (Cl, C2) arrive, each superconducting cable (Cl, C2) comprising a cable core surrounded by a cryogenic envelope (Cri, Cr2), and a plurality of connection assemblies located in said junction pit (F) so as to connect a respective pair of said superconducting cables, each connection set including a junction device (50, 60) comprising two connection ports (PI, P2), each connection port being configured to receive the core of a respective cable of the pair of superconducting cables, and at least one compensation device (22, 24, 26) configured to absorb a variation in length of the core of a first cable of the pair of superconducting cables (Cl, C2), caused by a variation in temperature for a transition to the superconducting state, the compensation device (22, 24, 26) comprising an input end (Ee) configured to receive the core of the first cable and an output end (Es) connected to one of said connection ports (PI, P2) so as to deliver the core of the first cable to the junction device (50, 60), the compensation device (22, 24, 26) comprising an inner tube (8) and an outer tube (7) coaxial between which vacuum insulation is provided, the inner tube (8) being configured to receive the core of the first superconducting cable and a cooling fluid intended to cool said core to a cooling temperature for a superconducting state, said inner and outer tubes having at least one curvature of an angle greater than or equal to 90, installation in which the axes (|3) of the curvatures of the compensation devices are parallel to each other.