The present invention relates to a method for erecting a transportation structure comprising an assembly of tube segments, capable of being placed under low air pressure and through which pods may travel substantially free of air friction. This transportation system is often referred to as the hyperloop technology. The present invention also relates to the corresponding transportation structure.

Hyperloop technology is a proposed high-speed transportation system for both passenger and freight transport. It is basically a sealed system of tubes with low air pressure through which a pod may travel substantially free of air resistance or air friction. It has three major components: a tube, a pod and stations. The tube is a large sealed, low-pressure system that can be constructed above, below or on the ground. It contains the necessary infrastructure to ensure levitation/suspension, propulsion, braking... A vehicle runs inside this controlled environment and is often referred to as a pod. The pod employs electric levitation (either electro-magnetic or electro-dynamic) or aerodynamic levitation (using airbearing skis) along with electromagnetic or aerodynamic propulsion to glide along a fixed guideway. A station is a facility where a pod can start or stop and where boarding/unboarding of passengers and loading/unloading of cargo are possible. A station is positioned at each extremity of the sealed system of tubes.

In the artists’ views, an above-ground hyperloop structure is often represented in the form of tube segments whose ends simply rest on piers regularly spaced. This design is very appealing, but it does not provide a full understanding of important challenges during installation steps. One of these challenges is that the tube segments are huge pieces that cannot be easily transported to the construction site, even more so when the terrain is steep or difficult to access or if the hyperloop route is far away from existing roads. To avoid the transport of tube segments, it is known notably from US9517901 to manufacture and assemble the tubes on land with a movable tube fabrication machine (illustrated on Figure 9A) operable to move on land and directed along construction route. Alternatively, a moveable in-situ manufacturing system (illustrated on Figure 9B) may be located at a single location to make a number of tube sections (e.g., fifty tube sections), and then subsequently moved to a new location. In both cases, hyperloop routes can only be constructed if the moveable fabrication machine or the moveable manufacturing system can access the construction site. Moreover, among other drawbacks, it is worth mentioning that the energy supply might be tricky when moving along the construction route and, each time the machine/system would be moved, new electrical certifications may have to be obtained.

The aim of the present invention is therefore to remedy the drawbacks of the methods and structures of the prior art by providing a method for erecting an above-ground transportation structure which is compatible with rough terrains and for which the shipping of the different elements of the structure and their assembly is made easier.

For this purpose, a first subject of the present invention consists of a method for erecting a portion of a transportation structure comprising:

- a plurality of piers substantially regularly spaced along the longitudinal axis X of the portion of transportation structure,

- a plurality of platforms connected to the piers and forming a service pathway running from a first extremity of the portion of the transportation structure to a second one.

- a first plurality of girders positioned on the piers and forming: o a first assembly of tube segments, the first assembly being capable of being placed under low air pressure and capable of allowing the circulation of pods travelling substantially free of air friction in the tube segments, o a first rooftop transportation pathway running from the first extremity of the portion of the transportation structure to the second one, each girder comprising: o a tube segment of the first assembly of tube segments, o a metallic structure embedding the tube segment of the first assembly of tube segments, the upper surface of the metallic structure being a portion of the first rooftop transportation pathway, the method comprising: o (i) starting from the first extremity of the portion of the transportation structure, conveying with vehicle(s) the nth girder of the first plurality of girders along the first rooftop transportation pathway formed by the (n-1) girders of the first plurality of girders previously positioned, positioning the nth girder at its use position and having the vehicle(s) return to the first extremity of the portion of the transportation structure along the service pathway, and o (ii) starting from the first extremity of the portion of the transportation structure, conveying with vehicle(s) the yth platform of the plurality of platforms along the first rooftop transportation pathway formed by the girders of the first plurality of girders previously positioned, positioning the yth platform at its use position and having the vehicle(s) return to the first extremity of the portion of the transportation structure along the service pathway.

The method according to the invention may also have the optional features listed below, considered individually or in combination:

- the method comprises, before step i), a step of erecting the piers,

- the method comprises, before step i), an additional step wherein a girder from the first plurality of girders and at least a platform of a first section of the portion of the transportation structure are erected at a stocking site,

- in steps i) and ii), the vehicles are set up with the girder and the platform at the first extremity of the portion of the transportation structure,

- the girders are positioned with a girder launcher crane supported by the structure itself, - the step of erecting the xth section doesn’t include positioning the nth girder of a second plurality of girders,

- The method further comprises the step of asynchronously erecting a second plurality of girders positioned on at least some of the piers and forming: o a second assembly of tube segments, the second assembly being capable of being placed under low air pressure and capable of allowing the circulation of pods travelling substantially free of air friction in the tube segments, o a second rooftop transportation pathway running from the first extremity of the portion of the transportation structure to the second one, alongside the first rooftop transportation pathway, the asynchronous erecting step comprising, starting from the first extremity, conveying with vehicle(s) the nth girder of the second plurality of girders either along the first rooftop transportation pathway or along the second rooftop transportation pathway, positioning the nth girder at its use position and having the vehicle(s) return to the first extremity of the portion of the transportation structure along the service pathway 9.

A second subject of the invention consists of a portion of a transportation structure for pods travelling substantially free of air friction in an assembly of tube segments placed under low air pressure, the portion of the transportation infrastructure comprising:

- a plurality of piers substantially regularly spaced along the longitudinal axis X of the portion of the transportation structure,

- a plurality of platforms connected to the piers and forming a service pathway running from a first extremity of the portion of the transportation structure to a second one.

- a first plurality of girders positioned on the piers and forming: o a first assembly of tube segments, the first assembly being capable of being placed under low air pressure and capable of allowing the circulation of pods travelling substantially free of air friction in the tube segments, o a first rooftop transportation pathway running from the first extremity of the portion of the transportation structure to the second one, each girder comprising: o a tube segment of the first assembly of tube segments, o a metallic structure embedding the tube segment of the first assembly of tube segments, the upper surface of the metallic structure being a portion of the first rooftop transportation pathway.

The portion of transportation structure according to the invention may also have the optional features listed below, considered individually or in combination:

- The portion of transportation structure further comprises a second plurality of girders positioned on the first plurality of girders and forming: o a second assembly of tube segments, the second assembly being capable of being placed under low air pressure and capable of allowing the circulation of pods travelling substantially free of air friction in the tube segments, o a second rooftop transportation pathway running from the first extremity of the portion of the transportation structure to the second one, each girder of the second plurality comprising: o a tube segment of the second assembly of tube segments, o a metallic structure embedding the tube segment of the second assembly of tube segments, the upper surface of the metallic structure being a portion of the second rooftop transportation pathway.

- each girder further comprises a tube segment of a second assembly of tube segments, positioned adjacent to the tube segment of the first assembly, the metallic structure embedding both tube segments, so that the plurality of girders positioned on the piers further forms a second assembly of tube segments capable of being placed under low air pressure and capable of allowing the circulation of pods travelling substantially free of air friction in the tube segments,

- the portion of transportation structure further comprises a second plurality of girders positioned on the first plurality of girders and forming: o a third assembly and a fourth assembly of tube segments, both assemblies being capable of being placed under low air pressure and capable of allowing the circulation of pods travelling substantially free of air friction in the tube segments, o a second rooftop transportation pathway running from the first extremity of the portion of the transportation structure to the second one, each girder of the second plurality comprising: o a tube segment of the third assembly of tube segments, o a tube segment of the fourth assembly of tube segments, o a metallic structure embedding the tube segment of the third assembly and the tube segment of the fourth assembly of tube segments, the upper surface of the metallic structure being a portion of the second rooftop transportation pathway.

- the metallic structure comprises a lower deck, an upper deck and transverse reinforcements connecting the lower deck to the upper deck,

- each transverse reinforcement extends substantially in a plane perpendicular to the longitudinal axis X of the portion of transportation structure,

- each transverse reinforcement extends horizontally so as to match the contour of the cross-section of the tube segment,

- the upper deck is a substantially flat surface suitable for vehicle traffic,

- the metallic structure comprises transverse reinforcements and longitudinal reinforcements connecting the transverse reinforcements,

- each girder extends from one pier to the adjacent one,

- the portion of transportation structure does not comprise a second plurality of girders positioned on at least some of the piers and forming a second rooftop transportation pathway alongside the first rooftop transportation pathway.

As it is apparent, the invention is based on the construction of a structure composed of piers, platforms and girders comprising tube elements of the highspeed transportation system and which can withstand the transportation of heavy parts like girders and platforms. The structure comprises a circulation loop so that, starting from a stocking site, vehicles circulating on the portion of the structure already in place can transport each additional element of the transportation structure to its position at the construction site and return to the stocking site without preventing other vehicles from transporting the next elements to the construction site. The transportation structure can thus be easily constructed whatever the terrain.

Other characteristics and advantages of the invention will be described in greater detail in the following description.

The invention will be better understood by reading the following description, which is provided purely for purposes of explanation and is in no way intended to be restrictive, with reference to:

- Figure 1 , which is a view of a portion of transportation structure according to a first variant of the invention,

- Figure 2 which is detailed view of a girder according to one variant,

- Figure 3, which is a view of a portion of transportation structure according to a second variant of the invention,

- Figure 4 which is detailed view of a girder according to one variant,

- Figure 5, which is detailed view of the internal structure of the girder of Figure 5,

- Figure 6, which is a view of a portion of transportation structure according to a third variant of the invention,

- Figure 7, which illustrates the erection of the piers of a portion of transportation structure,

- Figure 8, which illustrates the erection of a first section of a portion of transportation structure according to the second variant of the invention, - Figure 9, which illustrates loading girders at the stocking site on vehicles positioned on a first section of a portion of transportation structure according to the second variant of the invention,

- Figure 10, which illustrates conveying platforms to the construction site along the first transportation pathway of the portion of transportation structure according to the second variant of the invention,

- Figure 11 , which illustrates conveying girders to the construction site along the first transportation pathway of the portion of transportation structure according to the second variant of the invention,

- Figure 12, which illustrates positioning girders at the construction site,

- Figure 13, which illustrates conveying girders to the construction site along the first transportation pathway of the portion of transportation structure according to the first variant of the invention,

- Figure 14, which illustrates conveying platforms to the construction site along the first transportation pathway of the portion of transportation structure according to the first variant of the invention,

- Figure 15, which illustrates positioning girders at the construction site,

- Figure 16, which illustrates conveying girders to the construction site along the first transportation pathway of the portion of transportation structure according to the third variant of the invention.

It should be noted that spatially relative terms such as “lower”, “beneath”, “inward”, “inwards”, “outward”, “outwards”... as used in this application refer to the positions and orientations of the different elements of the portion of transportation structure once the latter has been erected. “Upstream” and “downstream” as used in this application refer to the direction of assembling when starting from a stocking site.

With reference to Figures 1 to 6, the portion of transportation structure 1 according to the invention first comprises a plurality of piers 3, a plurality of platforms 8 connected to the piers and a first plurality 4 of girders 6 positioned on the piers. A portion of transportation structure is composed of a plurality of sections, preferably at least 3 sections. A section is defined by the length of a girder. It preferably matches the distance between two consecutive piers along the longitudinal axis X of the portion of the transportation structure.

A pier 3 is an upright support for a structure or superstructure such as an arch or bridge. It supports the superstructure and transfers loads of the superstructure to the foundations. The shape of the piers according to the invention is not particularly limited as long as they can support the girders and the platforms.

According to a first variant illustrated on Figure 1 , the piers are pile bent piers, i.e. piers made of two or more columns supporting a pier cap. The piers substantially extend in a plan perpendicular to the route, i.e. perpendicular to the girders’ length.

According to a second variant illustrated on Figure 3, the piers are V- shaped. The V substantially extends in a plan perpendicular to the route, i.e. perpendicular to the girders’ length. The piers comprise two inclined arms, extending outwards. They can also comprise a pier cap, in the form of a horizontal beam linking the two arms. This pier cap provides additional seating for the girders and better distributes the load from the girders to the piers.

Others shapes such as Y, X, H, hammerhead piers, cantilevered piers, trestle piers, solid piers, simple columns are also possible.

The piers are substantially regularly spaced along the longitudinal axis X of the portion of the transportation structure.

The portion 1 of transportation structure according to the invention further comprises a plurality of platforms 8 positioned along the longitudinal axis X and forming a service pathway 9 running from a first extremity of the portion of the transportation structure to a second one. By service pathway, it is meant at least one continuous track designed to withstand vehicle traffic. In particular, it is not designed to withstand the transportation of heavy parts like girders and platforms. The service pathway extends from the first longitudinal extremity of the portion of transportation structure to the second longitudinal extremity of the portion of transportation structure, whatever the length of the portion. For the sake of clarity, the service pathway is above ground. It runs substantially parallel to the longitudinal axis X of the portion of transportation structure.

A platform is a light structure suitable for vehicle traffic. The platforms are preferably made of steel. They preferably comprise a traffic deck, i.e. a surface suitable for vehicle traffic, possibly reinforced underneath by longitudinal reinforcements and/or transversal reinforcements. These reinforcements add structural rigidity to the traffic deck. The traffic deck can also comprise safety rails along the longitudinal edges of the traffic deck for safety reasons. The traffic deck, the reinforcements and the safety rails are preferably made of steel. The traffic deck is preferably a perforated surface, like a perforated steel sheet or metal grid.

The platforms 8 are connected to the piers. Preferably, the longitudinal ends of the platforms are connected to the piers. In that case, the platforms have preferably the same length as the girders. Consequently, the piers can comprise a bearing area 19, which can be for example a portion of the shape itself of the piers or an anchor point added to the pier. In the case illustrated on Figure 1 , the bearing area 19 is in the form of a protrusion extending above a part of the pier cap. In that case, the platforms of the service pathway, in particular their longitudinal ends, can simply rest on the protrusions. In the case illustrated on Figure 3, the bearing area 19 is in the form of a protrusion extending inwards from an arm of the V-shaped pier. In that case, the platforms of the service pathway, in particular their longitudinal ends, can simply rest on the protrusions. Preferably, the two arms comprise a bearing area. More preferably, the bearing areas of the two arms of a given pier are substantially flush, i.e. at the same level, so that the platforms of the service pathway can more stably rest on the bearing areas. Alternatively, the platforms of the service pathway can rest on other parts of the pier, such as the horizontal beam of a H-shaped pier if applicable, or can be anchored to a column.

Thanks to the service pathway 9, during the construction phase, the vehicles having moved an element to the construction site can return to the stocking site without preventing other vehicles from transporting the next elements to the construction site. It speeds up the transportation of the elements to the construction site and thus shortens the erection phase. This advantage will be further detailed when describing the erection method. During operation, the service pathway can be advantageously used for maintenance, inspection and/or as an escape route. The service pathway can be permanent or temporary.

According to a first embodiment of the portion of the transportation structure illustrated on Figures 1 and 2, the portion of transportation structure also comprises a first plurality 4 of girders 6 positioned on the piers 3 and forming:

- a first assembly 12 of tube segments 14, the first assembly being capable of being placed under low air pressure and capable of allowing the circulation of pods travelling substantially free of air friction in the tube segments, and

- a first rooftop transportation pathway 7 running from the first extremity of the portion of the transportation structure to the second one.

Accordingly, each girder 6 comprises: o a tube segment 14 of the first assembly of tube segments, o a metallic structure 20 embedding the tube segment of the first assembly of tube segments, the upper surface of the metallic structure being a portion of the first rooftop transportation pathway.

A girder 6 is a support beam used in construction. It can be made of steel or concrete or it can be a composite structure. It can be a box girder, i.e. a girder that has a cross-sectional closed contour.

The design of the tube segments 14 is not limited as long as they can be connected to one another, by their longitudinal ends, directly or indirectly, along the longitudinal axis so as to form an assembly as described above. In particular, the cross-section of the tube is not limited. It can notably be a circular crosssection or a polygonal cross-section.

The tube segments are preferably made of steel. Steel has the advantages of being light, easily vacuum-tight and recyclable.

According to one variant of the invention, the tube segment is made of steel plates welded to one another.

According to another variant, the tube segment comprises a plurality of wall segments connected together by their longitudinal edges. Adjacent wall segments are arranged edge to edge along a junction line. Their edges can comprise flanges to ease the assembling. Each wall segment can comprise at least one central panel and two side panels. The side panels extend on both sides of the central panel over the circumference of the tube segment. They laterally enclose the central panel. The side panels form an angle with the central panel(s). This type of wall segment has the advantage of being easily obtained by simple folding of a metal sheet. The side panels stiffen the wall segments and increase the bending strength of said segments in the longitudinal direction.

According to another variant, the tube segment is a double-walled tube segment wherein the space between the exterior tube and the interior tube is filled with a stiffening compound.

According to another variant, the tube segment comprises a plurality of longitudinal stringers mounted to a plurality of circumferential sections to form a skeletal framework, on which skin sections are attached air-tightly.

According to another variant, the tube segment comprises a plurality of elongated outer skin panels forming the outer wall of a double-walled tube segment. The panels are curved so that their assembling form a smooth cylindrical surface. They can have embossed indentation to increase buckling resistance. The tube segment also comprises inner sheet parts, forming the inner wall of the double-walled tube segment, welded to each other to obtain a an airtight connection and welded to the elongated outer skin panels.

According to another variant, the tube segment comprises elongated curved outer shell parts forming the outer wall of a double-walled tube segment, an inner wall in the form of a regular N-facetted polygonal tube, and interlayer shell parts whose inward side is flat and whose outward side has the same curvature as the elongated curved outer shell parts.

By “low air pressure”, it is meant an air pressure below atmospheric pressure, preferably below or equal to 10 kPa, more preferably between 10 Pa and 10 kPa.

Practically speaking, the capability of the assembly to be placed under low air pressure is conferred by the features of the tube segment wall, the features of the connection between tube segments and the pumping equipment. In particular, the tube segment wall has to be airtight. Different ways of making a tube wall airtight are well known and the person skilled in the art will know how to select the features of the wall in each specific case. Also, the connection between two tube segments has to be airtight. The airtightness of the connection can notably be provided by welding, by the addition of components such as an elastomer between tube segments that are bolted or clamped, or by means of an expansion joint. The person skilled in the art knows how to make connections airtight and will adapt the connection to each specific case. Also, the pumping equipment has to be correctly dimensioned so that a low air pressure can be reached and maintained in the assembly of tube segments, while taking into account the air leakages under operation. The person skilled in the art knows how to do so and will adapt the pumping equipment to each specific case.

Practically speaking, the capability of the assembly to allow the circulation of pods travelling substantially free of air friction in the tube segments is conferred by the infrastructure positioned inside the tube segments and which provide notably the levitation/suspension, propulsion, braking... Such infrastructures are already well known and the person skilled in the art will know how to adapt the infrastructure to each specific case.

The girder further comprises a metallic structure 20 embedding the tube segment of the first assembly of tube segments, the upper surface of the metallic structure being a portion of the first rooftop transportation pathway.

In a first variant of the metallic structure illustrated on Figure 2, the metallic structure can comprise a lower deck 21 , an upper deck 22 and transverse reinforcements 23 connecting the lower deck to the upper deck.

The lower deck 21 is substantially a flat part extending horizontally. It is preferably made of plates, such as steel plates. It is more preferably reinforced with longitudinal stiffeners 24. The lower deck increases the rigidity of the girder and limits the deflection of the girder between its supports.

The upper deck 22 can be a flat part extending horizontally. It is preferably made of plates, such as steel plates. It is more preferably reinforced with longitudinal stiffeners. The upper deck increases the rigidity of the girder and limits the deflection of the girder between its supports. The upper surface of the upper deck forms a portion of the first rooftop transportation pathway 7.

The transverse reinforcements 23 extend substantially in a plane perpendicular to the longitudinal axis X of the portion of transportation structure. They extend horizontally to delimit the width of the girder and to stiffen the lower deck and the upper deck they are connected to. They extend vertically to delimit the thickness of the girder and to further stiffen the girder. In particular, they extend to the level of or above the top of the tube segment so that they can be connected directly to the upper deck. In particular, they extend to the level of or below the bottom of the tube segment so that they can be connected directly to the lower deck. They are preferably spaced along the length of the girder, i.e. along the longitudinal axis X. More preferably, they are regularly spaced. They can be made of, for example, flat panels, corrugated panels or flat panels reinforced with stiffeners.

According to the first variant of the metallic structure illustrated on Figure 2, a transverse reinforcement 23 extends horizontally so as to match the contour of the cross-section of the tube segment. It further stiffens the tube segment and the girder. The transverse reinforcement preferably comprises two transverse reinforcement sections 25, one on each side of the tube segment. In particular, a transverse reinforcement section positioned on one side of the tube segment faces the transverse reinforcement section positioned on the other side of the tube segment.

Alternatively, a transverse reinforcement can comprise a lower horizontal beam positioned below the tube segment, an upper horizontal beam positioned above the tube segment and at least one vertical beam connected to the lower and upper horizontal beams. The transverse reinforcement preferably comprises two vertical beams positioned on each side of the tube segment, connected to the lower and upper horizontal beams so as to form a square cross-section embedding the tube segment.

According to a second variant of the metallic structure (not illustrated), the metallic structure embedding the tube segment can comprise transverse reinforcements and longitudinal reinforcements connecting the transverse reinforcements. The transverse reinforcements can be as described above. The longitudinal reinforcements are preferably beams, in particular I-beams. The longitudinal reinforcements can be positioned below the transverse reinforcements, as lower longitudinal reinforcements and/or above the transverse reinforcements, as upper longitudinal reinforcements. The girder preferably comprises two pluralities of longitudinal reinforcements, one on each side of the tube segment.

In this variant, the upper surface of the upper longitudinal reinforcements forms a portion of the first rooftop transportation pathway. In particular, the upper surfaces comprise rails forming a railroad, so that railway vehicles can move along the railroad.

Preferably each girder extends from one pier to the adjacent one. In particular the first end of the girder rests on a given pier and the second end of the girder rests on an adjacent pier along the longitudinal axis X of the portion of the transportation route or structure. The girders can thus be easily installed by simply positioning them on the piers. Alternatively, a girder can extend on more than two piers.

The first plurality 4 of girders 6 is positioned along the longitudinal axis of the portion of the transportation route or structure, so as to form a first rooftop transportation pathway 7. In particular, all the girders 6 of the first plurality 4 of girders are positioned successively and continuously one after the other along the longitudinal axis X of the portion of the transportation structure, so as to form a first rooftop transportation pathway 7. By rooftop transportation pathway, it is meant at least one continuous track on the girders designed to withstand the transportation of heavy parts like girders and platforms with vehicles. The rooftop transportation pathway extends from the first longitudinal extremity of the portion of the transportation structure to the second longitudinal extremity of the portion of the transportation structure, whatever the length of the portion.

According to one variant of the rooftop transportation pathway, the upper surface of the girder, in particular of the upper deck, is simply a substantially flat surface suitable for vehicle traffic.

According to another variant of the rooftop transportation pathway, the upper surface of the girder, in particular of the upper deck, comprises rails forming a railroad, so that railway vehicles can move along the railroad.

Thanks to the first plurality 4 of girders, during the construction phase, vehicles circulating on the first rooftop transportation pathway formed by the girders already in place can easily transport each additional element of the portion of transportation structure to its position. Access to the ground along the construction route is not necessary anymore. This advantage will be further detailed when describing the erection method.

According to a second embodiment of the portion of the transportation structure illustrated on Figures 3 to 5, each girder 6 of the first plurality 4 of girders comprises a tube segment 14 of the first assembly 12 of tube segments and a tube segment 14 of a second assembly 13 of tube segments, positioned adjacent to the tube segment of the first assembly 12. In that case, the metallic structure 20 embeds both tube segments, so that the first plurality 4 of girders positioned on the piers forms a first assembly 12 of tube segments and a second assembly 13 of tube segments, both assemblies being capable of being placed under low air pressure and capable of allowing the circulation of pods travelling substantially free of air friction in the tube segments.

The characteristics and variants of the tube segments of the first assembly detailed above also apply to the tube segments of the second assembly. Tube segments of the first assembly and tube segments of the second assembly can be identical to ease logistics.

The characteristics and variants of the metallic structure described in the first embodiment of the portion of the transportation structure also apply to the second embodiment of the portion of the transportation structure.

In particular, each transverse reinforcement 23 of the metallic structure illustrated on Figures 4 and 5 comprises three transverse reinforcement sections 25, one on the outward side of the first tube segment, one in-between the two tube segments and one on the outward side of the second tube segment. More particularly, the three transverse reinforcement sections are positioned substantially in the same plane.

According to a third embodiment of the portion of the transportation structure, the portion of transportation structure also comprises a first plurality 4 of girders 6 as described in the first and second embodiment and a second plurality 5 of girders positioned on the first plurality 4 of girders, in particular on the first rooftop transportation pathway 7. This positioning limits the footprint of the transportation structure. It also reduces the amount of switches and facilitates surface use, in particular for deviating towards stations. The characteristics and variants of the girders of the first plurality detailed above also apply to the girders of the second plurality. Girders of the first plurality and girders of the second plurality can be identical to ease logistics.

In the example illustrated on Figure 6, the first plurality 4 of girders is similar to the one described in the first embodiment and the second plurality 5 of girders 6 forms:

- a second assembly 13 of tube segments, the second assembly being capable of being placed under low air pressure and capable of allowing the circulation of pods travelling substantially free of air friction in the tube segments,

- a second rooftop transportation pathway 10 running from the first extremity of the portion of the transportation structure to the second one,

Accordingly, each girder 6 of the second plurality 5 comprises:

- a tube segment 14 of the second assembly 13 of tube segments,

- a metallic structure 20 embedding the tube segment of the second assembly of tube segments, the upper surface of the metallic structure being a portion of the second rooftop transportation pathway.

In another example not illustrated, the first plurality 4 of girders is similar to the one described in the second embodiment and the second plurality 5 of girders 6 forms:

- a third assembly and a fourth assembly of tube segments, both assemblies being capable of being placed under low air pressure and capable of allowing the circulation of pods travelling substantially free of air friction in the tube segments,

- a second rooftop transportation pathway 10 running from the first extremity of the portion of the transportation structure to the second one,

Accordingly, each girder of the second plurality comprises: o a tube segment 14 of the third assembly of tube segments, o a tube segment 14 of the fourth assembly of tube segments, o a metallic structure 20 embedding the tube segment of the third assembly and the tube segment of the fourth assembly of tube segments, the upper surface of the metallic structure being a portion of the second rooftop transportation pathway. According to a first embodiment of the portion of transportation structure, the portion of the transportation structure does not comprise a second plurality of girders positioned on at least some of the piers and forming a second rooftop transportation pathway alongside the first rooftop transportation pathway.

According to a second embodiment of the portion of transportation structure (not illustrated), the portion 1 of transportation structure further comprises a second plurality of girders 6 positioned on at least some of the piers and forming:

- a second assembly of tube segments 14, the second assembly being capable of being placed under low air pressure and capable of allowing the circulation of pods travelling substantially free of air friction in the tube segments, and

- a second rooftop transportation pathway running from the first extremity of the portion of the transportation structure to the second one, alongside the first rooftop transportation pathway. each girder of the second plurality comprising: o a tube segment 14 of the second assembly of tube segments, o a metallic structure 20, i.e. a second metallic structure, embedding the tube segment of the second assembly of tube segments, the upper surface of the metallic structure being a portion of the second rooftop transportation pathway.

The characteristics and variants of the tube segments of the first assembly detailed above also apply to the tube segments of the second assembly. Tube segments of the first assembly and tube segments of the second assembly can be identical to ease logistics. The characteristics and variants of the metallic structure described above also apply here. The definition and variants detailed in relation to the first plurality of girders apply to the second plurality of girders. Girders of the first plurality and girders of the second plurality can be identical to ease logistics. The definition and variants detailed in relation to the first rooftop transportation pathway apply to the second rooftop transportation pathway.

By alongside, it is meant that both rooftop transportation pathways are substantially parallel to each other and run adjacent to each other. It is not limited to rooftop transportation pathways at the same level and/or rigorously parallel. The space between the first and second rooftop transportation pathways and/or the level of the first and second rooftop transportation pathways can be adjusted to the topography of land.

With reference to Figures 7 to 16, the method for erecting the portion 1 of transportation structure according to the invention will now be described.

In a first step, illustrated on Figure 7, the piers 3 of the portion 1 of the transportation structure are erected. They can be erected with any suitable method, such as panel formwork for example. Their erecting method includes the erection of piers foundations as required by the nature of the ground. This step can be done before the step of positioning the girders 6 or at least partially at the same time as the step of positioning the girders. In other words, the piers can be erected well before the girder positioning starts, for example weeks before. This notably gives time for concrete drying and soil compaction. Alternatively, some piers are still being erected when the girder positioning starts on the first erected piers.

As the footprint for erecting piers is limited and only light-duty vehicles are needed (bulldozers, concrete mixer trucks), the piers are preferably erected by ground access to the construction site of each pier.

In a second step of erecting the portion of the transportation structure, the girders 6 and platforms 8 are erected.

As mentioned above, the erection of girders and platforms starts from a stocking site 15 where at least part of the elements of the transportation structure are stocked. Depending on the ease of transporting the elements up to the stocking site, some elements can be manufactured at the stocking site in manufacturing facilities. It can for example be the case of the tube segments, of the metallic structures or of the girders which are massive pieces. Manufacturing some elements on the stocking site minimizes the erection time at the construction site and it allows for better quality control of the manufactured elements.

The stocking site 15 is preferably located at the future site of a station, in particular a passenger and/or freight station. This limits the footprint of the construction phase. It also limits the civil work. In particular, the civil work done to build the stocking site and its optional manufacturing facilities can be used for erecting the station. The stocking site is preferably located at the ground level. As illustrated on Figure 8, the first sub-step in erecting the girders 6 and platforms 8 is at the stocking site 15. This sub-step comprises the erection, at the stocking site, of a girder 6 from the first plurality of girders and at least a platform 8 forming at least part of a first section of the structure. In particular, this sub-step comprises positioning a girder from the first plurality of girders on at least one pier. This positioning is preferably done with a crane 16 which can pick the elements on the stocking site and move them to the piers. The assembling order of the girder(s) and platform(s) can vary depending on the design of the structure and notably depending on how the platform is linked to the rest of the structure.

According to a first variant, the first section of structure comprises one single pier. This is notably the case when the stocking site is positioned on a high ground. The first extremity of the first girder can then rest on the high ground while the second extremity of the first girder can rest on the pier positioned downhill. In that case, the first sub-step comprises positioning a girder from the first plurality of girders between the high ground and the pier.

According to a second variant illustrated on Figure 8, the first section of structure comprises two piers. This is notably the case when the stocking site is positioned on a substantially flat ground. The first extremity of the first girder can then rest on the first pier while the second extremity of the first girder can rest on the second pier. In that case, the first sub-step comprises positioning a girder from the first plurality of girders on the two piers.

This first sub-step can comprise the erection, at the stocking site, of other sections, or parts of sections, of the structure. The number of sections, or parts of sections, erected at the stocking site is conditioned by the ability of the crane from the stocking site to position the elements on the piers.

Once the girder of the first plurality and the platform(s) of the first section of the structure has been erected, the first section comprises a first extremity adjacent to the stocking site and a second extremity at its opposite end. The first extremity of the first section corresponds to the first extremity of the portion of transportation structure erected according to the invention. Consequently, the position of the first extremity of the portion of transportation structure erected according to the invention will not change over time during the erection of the portion of transportation structure. As for the second extremity of the first section, it corresponds to the second extremity of the structure under construction, as long as no other section of structure has been erected downstream of the first section. In other words, the position of the second extremity of the structure under construction will change over time each time a new section is erected downstream of the already erected sections of transportation structure.

Thanks to the elements composing the erected structure, vehicles 17 can circulate on the first rooftop transportation pathway 7 formed by at least one girder 6 of the first plurality 4 of girders and on the service pathway 9 formed by at least one platform 8. In particular, vehicles moving the elements to be positioned along the construction route can circulate on the first rooftop transportation pathway, starting from the first extremity and up to the second extremity of the structure under construction. Once the elements have reached their use position, the vehicles can return to the first extremity via the service pathway.

Consequently, in a second sub-step in erecting the girders 6 and platforms 8, the girder of the first plurality and the platform(s) of another section of the structure can be erected as detailed hereafter. This section is referred to below as “the second section” for simplicity, assuming that only the girder of the first plurality and the platform (s) of a first section has been erected at the stocking site.

The second section of the structure comprises one girder 6 of the first plurality 4 of girders, at least one platform 8 of the plurality of platforms and at least one pier 3 of the structure.

As explained above with regard to the pier erection, at least an additional pier has been erected downstream of the first section of the structure.

Vehicles 17 suitable for the transport of heavy elements are positioned on the first section of the structure, in particular on the first rooftop transportation pathway 7, more particularly on the first girder 6 of the first plurality 4 of girders. The vehicles can be lifted with a crane 16 or can reach their position with an access ramp or any other suitable equipment. The type of vehicles is not limited. It can be wheeled vehicles, such as trucks or train locomotives. Depending on the type of vehicles, the element(s) to be transported can be either loaded on one vehicle or loaded on several vehicles at the same time or the vehicle can be simply connected to the element(s), as in the case of a train locomotive for the transport of element(s) equipped of railroad wheels. In this description, the terms “set up” and “pair” are used to designate equally the loading of the vehicle(s) with an element and the connection of the vehicle(s) with an element. The term “freed” is used to designate equally the unloading of an element from the vehicle(s) and the disconnection of the vehicle(s) with an element.

Some vehicles are set up with the girder of the first plurality and the platform(s) of the second section of the structure. In particular, vehicle(s) are set up with one girder 6 of the first plurality 4 of girders and vehicle(s) are set up with at least one platform 8. The elements can be conveyed from the stocking site on the first section of the structure or can be lifted from the stocking site up to the first section of the structure with a crane. In the first case, they can be conveyed by the vehicles themselves. In the second case, the vehicles can be positioned and then set up.

The elements are then conveyed with the vehicles from the first extremity to the second extremity of the structure under construction, which is adjacent to their use position. In particular:

- The girder 6 of the first plurality 4 of girders is conveyed along the first rooftop transportation pathway 7 formed by the girders of the first plurality of girders already positioned,

- The at least one platform 8 is conveyed along the first rooftop transportation pathway.

The order in which the elements are paired with vehicles and conveyed to the second extremity is not limited. Also, some elements can be conveyed to the second extremity while others are still being set up on vehicles.

Once an element has been conveyed to the second extremity of the structure under construction, it is positioned at its use position, i.e. its position of service in the structure. In particular:

- The girder 6 of the first plurality 4 of girders is positioned downstream of the first rooftop transportation pathway 7. In particular, it is positioned after the girder of the first rooftop transportation pathway forming the second extremity of the structure under construction. More particularly, it is positioned in line with the girder 4 of the first rooftop transportation pathway 7 forming the second extremity along the longitudinal axis X. Even more particularly, it is positioned so that a first end of the girder rests on the pier forming the second extremity of the first section of structure and a second end of the girder rests on the at least one additional pier erected downstream of the first section of structure. The girder of the first plurality of girders is preferably positioned with a crane 18, more preferably with a girder launcher crane, supported by the structure itself.

- The at least one platform 8 is positioned downstream of the service pathway 9. In particular, it is positioned after the platform of the service pathway forming the second extremity of the structure under construction. More particularly, it is positioned in line, along the longitudinal axis X, with the platform of the service pathway forming the second extremity. Even more particularly, it is positioned so that a first end of the platform rests on the pier forming the second extremity of the first section of structure and a second end of the platform rests on the additional pier erected downstream of the first section of structure. The at least one platform is preferably positioned with the crane, more preferably with the girder launcher crane.

The use of a crane 18 supported by the structure is beneficial. It further limits the footprint of the erection by eliminating the need for ground access to the construction site and ground preparation for a crane. It also makes the erecting method further independent of the topography and roughness of the terrain.

Once an element has been positioned, the corresponding freed vehicle(s) can return to the first extremity of the structure along the service pathway. In particular:

- The vehicle(s) 17 freed from the girder 6 of the first plurality 4 of girders is moved from the first rooftop transportation pathway 7 to the service pathway 9. In the case where the service pathway is not at the level of the first rooftop transportation pathway, the vehicle(s) can be lifted by a crane and put down on the service pathway. Preferably it is lifted with the girder launcher crane.

- The vehicle(s) 17 freed from the at least one platform 8 is moved from the first rooftop transportation pathway 7 to the service pathway 9. In the case where the service pathway is not at the level of the first rooftop transportation pathway, the vehicle(s) can be lifted by a crane and put down on the service pathway. Preferably it is lifted with the girder launcher crane.

The order in which the elements are positioned is not limited. Also, some elements can be positioned while others are still being paired with vehicles or conveyed to the second extremity. Preferably, the at least one platform 8 is positioned first so that the vehicle(s) freed from the girder 6 of the first plurality 4 of girders can be more easily transferred to the service pathway.

Once the girder of the first plurality and the platform(s) of a second section of the structure have been erected as detailed above, girders of the first plurality and the platforms of other sections of the structure can be erected according to a similar process and as detailed below in relation to the erection of the girder of the first plurality and the platform(s) of the xth section of the structure.

The xth section of the structure comprises the nth girder 6 of the first plurality 4 of girders, at least the yth platform 8 of the plurality of platforms and at least the zth pier 3 of the structure. By default, x, y, z and n are different. In case where each section of the structure comprises one single platform, x is equal to n and y. In that case, the nth girder of the first plurality of girders is also the xth and the yth platform of the plurality of platforms is also the xth. In case where the first section comprises 2 piers and each section of the structure other than the first one comprises one single pier, z is equal to n+1 .

At least the zth pier 3 has first been erected downstream of the (x-1 ) first sections.

As illustrated on Figure 9, the vehicles 17 which have returned to the first extremity of the structure after being freed from the girder(s) and platform(s) of a previous section(s) of the structure are set up with the girder of the first plurality and the platform(s) of the xth section of the structure. In particular, vehicle(s) are set up with the nth girder of the first plurality of girders and vehicle(s) are set up with the yth platform of the plurality of platforms. If the xth section comprises additional platform(s), they are paired with the vehicles similarly.

As illustrated on Figures 10, 11 , 13 and 14, starting from the first extremity of the structure, the girder 6 of the first plurality and the platform(s) 8 of the xth section of the structure are conveyed with vehicles from the first extremity to the second extremity of the structure under construction, which is adjacent to their use position. In particular:

- The nth girder 6 of the first plurality 4 of girders is conveyed along the first rooftop transportation pathway 7 formed by the (n-1) girders of the first plurality of girders previously positioned,

- The yth platform 8 of the plurality of platforms is conveyed along the first rooftop transportation pathway 7 formed by the girders of the first plurality of girders previously positioned.

If the xth section comprises additional platform(s), they are conveyed similarly. The order in which the elements are paired with vehicles and conveyed to the second extremity is not limited. Also, some elements can be conveyed to the second extremity while others are still being paired with vehicles.

As illustrated on Figures 11 , 12, 14 and 15, once an element has been conveyed to the second extremity of the structure under construction, it is positioned at its use position. In particular:

- The nth girder 6 of the first plurality of girders is positioned downstream of the first rooftop transportation pathway 7. In particular, it is positioned after the girder of the first rooftop transportation pathway forming the second extremity of the structure under construction. More particularly, it is positioned in line, along the longitudinal axis, with the (n-1 )th girder of the first rooftop transportation pathway. Even more particularly, it is positioned so that a first end of the nth girder rests on the pier forming the second extremity (the (z-1 )th pier) and a second end of the nth girder rests on the zth pier erected downstream of the structure. The nth girder of the first plurality of girders is preferably positioned with a crane 18, more preferably with a girder launcher crane, supported by the structure itself,

- The yth platform 8 is positioned downstream of the service pathway. In particular, it is positioned after the (y-1 )th platform of the service pathway, i.e. the platform of the service pathway forming the second extremity of the structure under construction. More particularly, it is positioned in line, along the longitudinal axis, with the platform of the service pathway forming the second extremity. Even more particularly, it is positioned so that a first end of the yth platform rests on the pier forming the second extremity (the (z-1 )th pier) and a second end of the yth platform rests on the zth pier erected downstream of the structure. The yth platform is preferably positioned with a crane 18, more preferably with a girder launcher crane, supported by the structure itself,

As illustrated on Figures 11 , 12, 14 and 15, once an element of the xth section of structure has been positioned, the corresponding freed vehicle(s) can return to the first extremity of the structure along the service pathway. In particular:

- The vehicle(s) freed from the nth girder of the first plurality of girders is moved from the first rooftop transportation pathway 7 to the service pathway 9,

- The vehicle(s) freed from the yth platform is moved from the first rooftop transportation pathway 7 to the service pathway 9.

In the case where the service pathway is not at the level of the first rooftop transportation pathway, the vehicle(s) can be lifted by a crane and put down on the service pathway. Preferably it is lifted with the girder launcher crane.

If the xth section comprises additional platform(s), they are positioned similarly and the corresponding vehicles return to the first extremity similarly. The order in which the elements of the xth section are positioned is not limited. Also, some elements of the xth section can be positioned while other elements of the xth section or of subsequent sections are being paired with vehicles or conveyed to the second extremity. Preferably, the yth platform 8 is positioned first so that the vehicle(s) conveying the nth girder of the first plurality of girders can be more easily transferred from the first rooftop transportation pathway to the service pathway.

Optionally, the erecting step doesn’t include, concomitantly with conveying and positioning the nth girder of the first plurality of girders, conveying the nth girder of a second plurality of girders and positioning it at its use position alongside the nth girder of the first plurality of girders. In other words, the step of erecting the girder and the platform(s) of the xth section doesn’t include positioning the nth girder of a second plurality of girders. Yet in other words, the positioning of the (n+1 )th girder of the first plurality of girders is done before the nth girder of an optional second plurality of girders is positioned at its use position alongside the nth girder of the first plurality of girders.

At the end of the step of erecting the structure, the last girder of the first plurality of girders is positioned on the last piers of the structure. These piers can be adjacent to or shared with a second portion of transportation structure erected or being erected as an extension of the relevant portion of transportation structure along the longitudinal axis of the transportation route. This second portion of transportation structure is erected from a second stocking site, possibly at the future site of a station, located downstream of the relevant portion. This second portion of transportation structure is built by erecting its structure backwards of the erection of the structure of the relevant portion. In other words, each portion is built from a stocking site in direction of another stocking site and at some point, the two portions join. The last girder of the first plurality of girders of the relevant portion is thus adjacent to the last girder of the first plurality of the second portion so that there is a continuity in the first assembly 12 of tube segments 14.

Once all the sections of the portion of the transportation structure have been assembled at least in part, an optional second plurality 5 of girders can be positioned on the first plurality 4 of girders, in particular on the first rooftop transportation pathway 7. In that case, the girders 6 of the second plurality of girders can be conveyed with vehicles from the first extremity of the structure to their use position along the first rooftop transportation pathway, as described above with reference to the first plurality of girders. As the girders of the second plurality are positioned on the girders of the first plurality and block the first rooftop transportation pathway, this assembling is done backwards compared to the assembling of the first plurality of girders. In other words, the girders of the second plurality are first positioned at the second extremity of the structure under construction and then positioned one in front of the other in direction of the first extremity of the structure, i.e. one upstream of the other, as illustrated on Figure 16.

Alternatively, the second plurality of girders is erected forwards instead of backwards. In that case, the girders 6 of the second plurality of girders can be conveyed with vehicles from the fist extremity of the structure to their use position along the second rooftop transportation pathway formed by the girders of the second plurality of girders already positioned on the first rooftop transportation pathway. This assembling is similar to the one described above with reference to the first plurality of girders. In particular, at least one first girder of the second plurality of girders is positioned on the girder(s) of the first plurality of girder composing the first section of the structure. Then, vehicles suitable for the transport of heavy elements are positioned on the second rooftop transportation pathway formed by the girder(s) of the second plurality of girders already positioned. Vehicles are set up with girders of the second plurality of girders and convey the girders from the first extremity of the structure to the last girder of the second plurality positioned on the first rooftop transportation pathway.

According to one embodiment of the method for erecting a portion 1 of a transportation structure, the method further comprises an additional step wherein a second plurality of girders is assembled on the portion 1 of transportation structure in a staggered manner with respect to the assembly of the first plurality 4 of girders 6 and of the plurality of platforms 8. By “in a staggered manner” or by “asynchronously”, it is meant that the positioning of the girder of the first plurality of a given section of a portion of transportation structure comprising two pluralities of girders starts before the girder of the second plurality of the previous section has been positioned. In particular, the positioning of the (n+1 )th girder of the first plurality of girders is done before the nth girder of the second plurality of girders is positioned at its use position alongside the nth girder of the first plurality of girders.

According to one variant, the additional step starts after the first plurality 4 of girders 6 and the plurality of platforms 8 of the portion of transportation structure have been erected.

In particular, the method comprises the step of asynchronously erecting a second plurality of girders 6 positioned on at least some of the piers and forming: o a second assembly of tube segments 14, the second assembly being capable of being placed under low air pressure and capable of allowing the circulation of pods travelling substantially free of air friction in the tube segments, o a second rooftop transportation pathway running from the first extremity of the portion of the transportation structure to the second one, alongside the first rooftop transportation pathway, the asynchronous erecting step comprising, starting from the first extremity, conveying with vehicle(s) 17 the nth girder 6 of the second plurality of girders either along the first rooftop transportation pathway 7 or along the second rooftop transportation pathway, positioning the nth girder at its use position and having the vehicle(s) return to the first extremity of the portion of the transportation structure along the service pathway 9.

The way the girders of the second plurality of girders are conveyed and positioned is similar to the way the girders of the first plurality of girders are conveyed and positioned. The details and variants provided above with regards to the erecting method of the first plurality of girders apply here.

In particular, according to the variant wherein the additional step starts while the erection of the first plurality of girders is still under way, in a first sub-step, at least one girder of the second plurality of girders is positioned on at least one pier of the first section of the structure, alongside a girder of the first plurality. In a second sub-step, vehicles positioned on the second rooftop transportation pathway formed by the at least one girder already positioned are set up with one girder of the second plurality of girders. Then the latter is conveyed along the second rooftop transportation pathway formed by the girder(s) of the second plurality of girders positioned on the first section of structure. Then the girder 6 of the second plurality of girders is further positioned downstream of the second rooftop transportation pathway, alongside the nth girder of the first plurality. In particular, it is positioned after the girder of the second rooftop transportation pathway forming the second extremity of the second rooftop transportation pathway under construction. In other words, it is positioned alongside the nth girder of the first plurality. Finally, the vehicle(s) 17 freed from the girder 6 of the second plurality of girders is moved from the second rooftop transportation pathway to the service pathway 9 and return to the first extremity of the structure along the service pathway. In particular, according to the variant wherein the additional step starts only once the first plurality 4 of girders 6 and the plurality of platforms 8 of the portion of transportation structure have been erected, in a first sub-step, at least one girder of the second plurality of girders is positioned on at least one pier of the first section of the structure, alongside a girder of the first plurality. In a second substep, vehicles positioned on the first rooftop transportation pathway are set up with one girder of the second plurality of girders. Then the latter is conveyed along the first rooftop transportation pathway. Then the girder 6 of the second plurality of girders is further moved laterally and positioned downstream of the second rooftop transportation pathway, as detailed above. Finally, the vehicle(s) 17 freed from the girder 6 of the second plurality of girders is moved from the first rooftop transportation pathway to the service pathway 9 and return to the first extremity of the structure along the service pathway.

Once the first girders of the second plurality of girders have been erected as detailed above, the other girders can be erected according to a similar process.