NO320988B1 - Device for concrete construction in the sea, and method for installation of the same - Google Patents

Description

The invention relates to a device for concrete structures in the sea, facilities for the foundation of concrete structures in the sea, as well as a method for installing these.

The invention is particularly relevant where you have moderate loose mass deposits and want a reasonable foundation of prefabricated, floating concrete structures down through loose mass deposits to solid rock. For example, when building breakwaters, quays and or road connections.

A particular application is in tidal power plants of the type where you want to close off a strait or shallow water area with a dam. Such a dam can simultaneously form a road connection and provide housing for turbines that produce electrical energy from the tidal flow.

Another application is for houses for fish farming or a combination of energy production, fish farming and road connection.

GB 1313657 describes a method for forming a pier, where a floating module is placed close to land, a pile is mounted next to the floating module, whereupon the floating module can be mounted at the desired height using the pile. The assembled module is then used as a starting point for the further construction

GB 2055933 mentions a pond built up of movable modules which are placed in submerged and modular box systems which rest on the bottom, or in frameworks which stand on the bottom.

It is common knowledge to pre-fabricate large concrete structures in a dry dock or floating dock and then tow these to their destination. Examples are submerged tunnels to guide road traffic under rivers or lakes, and for offshore oil installations. It is also known to combine road/bridge connection with tidal energy production.

The most famous tidal energy plant is EDF's La Rance plant in France. Here, a total of 24 turbines produced an average of approx. 500 GWh of electrical power per years since 1973. Similar tidal facilities have also been built in Russia, China and Canada. The reason why tidal power plants have so far not been widespread lies primarily in the fact that the construction costs for such energy production have been high compared to hydropower, thermal power and/or nuclear power plants.

It is also widely known that mass production of standardized concrete sections on a factory floor is far more cost-effective than cast-in-place solutions.

It has been an important goal of the invention to develop a cost-effective method for building and anchoring concrete structures that can withstand the forces that the strongest tidal currents and storms can bring.

The present invention fulfills the above-mentioned objectives in that it provides a device for the construction of a barrier fully or partially submerged in water, including a housing and a support element, characterized in that - the housing is equipped at a first upper longitudinal edge with a number of jacks and at a second upper longitudinal edge, opposite said first edge, is equipped with said number of recesses, and that - the support element includes a hole element equipped with a plurality of longitudinally penetrating bores, which element at its lower end part is equipped with a deformation element and at its upper end part is designed for engagement with said jacks, where thus said hole element's upper part in an assembled state forms a support for respective jacks.

The house can advantageously be equipped with a flow channel and otherwise be adapted to the installation of a turbine and generator unit for the production of energy from tides that flow through said flow channel.

The house can advantageously be equipped with an internal room in fluid connection with the water outside the house, so that said room can be used for storing live fish.

The aforementioned jacks and recesses can advantageously be added to the house's corner sections.

Deformation element is advantageously designed as a skirt of a relatively soft metal, attached to the lower parts of said hole element.

The housing and the hole element are in a preferred embodiment made of reinforced concrete.

A majority of said housing and a majority of said hole elements can advantageously be mounted in series, thereby forming a barrier.

The invention further relates to a method for installing a barrier in water using a plurality of devices according to the invention, where the method is characterized by the following steps: a) placing a first of said houses in a partially submerged state on the bottom under a water surface, so that the long sides of the house which are equipped with said recesses face in the barrier's desired running direction b) placement of a first of said hole elements with said deformation zone in contact with said bottom and the upper part of the hole element at the level of said recess,

c) placement of reinforcement in said boreholes,

d) placement of a filling channel for concrete above the upper part of the hole element,

e) filling of concrete through said channel and into the boreholes, up to the level of said recess, so that these form a part that is complementary to said

jack,

f) removal of the filling channel,

g) after the filled concrete has hardened, placing a second of said houses parallel to said first house and in such a way that the jacks on the second of said houses

is supported by said complementary party,

h) repetition of steps a) to g) until a barrier is formed consisting of said plurality of houses and hole elements.

Preferred embodiments of the device according to the invention appear from the accompanying claims 2-9.

A particular advantage of the invention is the "skirt" or deformation zone of the soft material, for sealing against rock at the bottom of piles with subsequent casting. Furthermore, a central aspect of the invention is the possibility of connecting concrete sections by hanging the next section on the previous one, which also has the support for the bottom.

A preferred embodiment of the device according to the invention will now be described with reference to the accompanying drawings, where like parts are given like reference numbers. Figure 1 is a sectional view of a barrier consisting of a number of the device according to the invention.

Figure 2 is a perspective view of part of the device according to the invention.

Figure 3 is a perspective view of part of the device according to the invention.

Figures 4 - 6 are an illustration of part of the installation sequence to form a barri are similar to that shown in Figure 1. Figure 7 is a sectional view of a variant of the device according to the invention, installed on a

seabed.

Figure 8 is a perspective view of a part of the device according to the invention installed on

an ocean floor.

Figure 1 shows, as mentioned, a barrier consisting of a number (n) of the device according to the invention. Here, the deeper parts of the strait are used for energy production with eight turbines in each of their concrete "energy houses", while the shallower parts towards the land are equipped with three concrete sections 50 on each side, so-called "fish barns" for farming. Together with stone fillings on land, this forms carriageway 40 during the construction period for mobile cranes/land-based construction equipment and for future road traffic. Fig 2 shows on a larger scale such a fish shed or house 50 in concrete (without a roof), ready for towing in the sea from the construction dock to the assembly site. Appropriate size of such houses can e.g. be 5 m wide, 5 m high, 10 m long. The length of each fish barn gives the future width of carriageways. Figure 3 shows a foundation pile or hole element 3 for anchoring the house 50 (such as a fish barn or energy house) to solid rock. The element has continuous bores 14 in the longitudinal direction and is equipped with a "skirt" at its lower part. This "skirt" is a deformation zone 4 formed by a number of relatively soft metal plates attached to said hole element.

The system solution and the assembly procedure involve starting from a land side and gradually connecting new fish barns and/or energy houses to the previous unit. Between each unit, two piles driven down to solid rock are mounted. If necessary, these are supplemented with inclined piles to capture large water pressures from the tide and rough seas.

The house (the fish barns and the energy houses) 50 is provided on one long side with jacks 1 which means that during assembly they can be hung on one side on each pile top against the previous unit. On the opposite long side, the fish barns have recesses 2 with protruding rebar so that the poles are anchored to the pre-assembled house during the subsequent casting process.

Assembly starts with a layer of crushed stone being laid on the ground which is leveled to the correct height for the first house's 50a bottom (see figures 4 - 6). This is floated in place and filled with water so that it rests firmly on the bottom in a partially submerged state.

Stone and gravel masses are then filled towards the first house so that together they form the sub-base for the future driveway. Prefabricated reinforced concrete roof elements (hole elements) are laid out on the first house and form roadway 40 up to the free long side of this unit.

Thus, a mobile crane or similar can drive forward and place two units. of said hole element 3 in front of the first house. Fig. 4 shows this operation after three housings 50a, 50b, 50c have been assembled.

Fig. 3 shows a suitable pile shape for the purpose. It consists of a hole element 3 made of concrete with through holes 14 and which at its lower end is screwed onto plates 4 of mild steel. The purpose of this "skirt" or deformation zone 4 is that, after the pile has been pushed down through loose masses into solid rock, it should bend outwards and shape itself according to the rock formation to form a casing or formwork for subsequent concrete filling.

The next operation is to use the holes 14 in the hole element 3 as a drill guide for drilling anchoring holes in the rock for rock bolts/rebar, e.g. from the work basket on the mobile crane as shown in fig 5. Loose materials and sawdust inside the screen are washed out by flushing water down through the holes in fig. 3. Figure 6 shows the casting operation after appropriately shaped reinforcing bars 5 and a filler box 6 have been placed over the pile top. Concrete is poured in up to the top of the fish barn. This results in a cast-in-place pile base for solid rock and a pile top for recess 2. After the concrete has hardened, a good connection and support of the fish barns has been achieved near all 4 corners. After the filling box has been removed, a new pile top has also been obtained on which the next fish barn can be hung, as the filling box is designed so that it provides a mold for the pile top that fits into the jacks of the next fish barn 1. At the same time, a fixed casting connection to the previous fish barn has been achieved its recesses 2. Fig. 7 shows a section through the energy house / bridge connection section of the foundation in relatively deep water. In this example, the energy house foundation is to solid rock with four piles. Here, the piles are pressed down through loose materials and cast into solid rock at the bottom and at the top of the energy house in the same way as described above.

In order to prevent the tide from flowing between the energy house and the loose mass bottom, the inlet and outlet are covered with concrete elements 51 which force the water to flow over and in through the light opening for the turbine and emit power to it.

To further stiffen and seal the construction, the space between the original loose-mass base and energy house, as well as hole elements, can be filled up with sand and clay that is pumped up from the bottom outside and into the opening from above between the energy house and the inner set of piles. Figure 8 shows a principle sketch for the foundation for the house 50 used as a fish barn on mountain ground. Reference number 11 indicates rock to be blasted away, while a space 10 is formed bounded by a number of the hole elements 3 and the underlying solid rock 9. The figure shows that the hole elements 3 are anchored in the solid rock by means of bolts 8. The deformation zone is also shown 4. Threaded rock bolts 7 with washers and nuts extend from the hole elements 3 into the rock.

The system shown in Figure 8 will be used for the first fish shed in a series, where the rock bed is so steep and/or the current is so strong that the loose material substrate for the first unit does not provide satisfactory support. In other words, an alternative to what is shown in Figure 4.

A first unit can be advantageously used as an independent permanent or temporary berth. If a longer berth is needed, several units can be placed next to each other. Then, however, the jack system becomes less important. An example of such an application could be fish reception or fish slaughterhouses, where the cavity in the quay can be useful as a waiting cage for the fish (a buffer between the well boat and the fish slaughterhouse).

In the case of loose mass deposition, it may be necessary to ram or vibrate the pile down to come into contact with the rock bed, possibly with high-pressure flushing to remove loose mass within the "skirt".

The purposes of the casting process are both to cast the rock bolt anchorage into the bottom, so that the bolts do not rust away, and to reinforce the piles (the vertical hole elements) with concrete and any additional reinforcement, and to capture possible deviations in the shell length (based on pre-hand seismic), and to create a correct height and shape for the next connection, as well as to form a rigid connection with reinforcement and recess in the preceding concrete unit.

Component list

Claims (10)

1. Device for the construction of a barrier completely or partially submerged in water, including a housing (50) and a support element (3) characterized in that - the housing (50) is equipped at a first upper longitudinal edge with a number of jacks (1) and at a second upper longitudinal edge, opposite said first edge, is equipped with said number of recesses (2), and that - the support element includes a hole element (3) equipped with a plurality of longitudinally penetrating bores (14), which element (3) by its lower end part is equipped with a deformation element (4) and at its upper end part is designed for engagement with said jacks (1), where the upper part of the aforementioned hole element in an assembled state forms a support for respective jacks. 2. Device according to claim 1, characterized in that the housing (50) is equipped with a flow channel (31) and the housing is otherwise adapted to the installation of a turbine and generator unit for the production of energy from tides that flow through said flow channel. 3. Device according to claim 1, characterized in that the housing (50) is equipped with an internal space in fluid connection with the water outside the housing, so that said space can be used for storing live fish. 4. Device according to claim 1, characterized in that said jacks (1) and recesses (2) are added to the corner parts of the housing (50). 5. Device according to claim 1, characterized in that said deformation element is designed as a skirt of a relatively soft metal, attached to the lower parts of said hole element (3). 6. Device according to claim 1, characterized in that the housing (50) and the hole element (3) are made of reinforced concrete. 7. Device according to claim 1, characterized in that the housing (50) is a floating element. 8. Device according to any one of the preceding claims, characterized in that a plurality of said housing (50) and a plurality of said hole elements (3) are mounted in series, thereby forming a barrier. 9. Device according to claim 2, characterized in that the housing (50) is assigned to elements (51) placed between the housing and a bottom under the housing to prevent water from flowing between the housing and the bottom under the housing and to guide the water into the through-flow channel ( 31). 10. Method for installing a barrier in water using a majority of the device according to claims 1-8, characterized by the following steps: a) placing a first of said houses (50a) in a partially submerged state on the bottom below a water surface , so that the one of the long sides of the house which is equipped with said recesses (2) faces in the desired running direction of the barrier b) placement of a first of said hole elements (3a) with said deformation zone (4a) in contact with said bottom and the upper part of the hole element at level with said recess (2), c) placement of reinforcement (5) in said bores (14), d) placement of a filling channel (6) for concrete above the upper part of the hole element (3 a), e) filling of concrete through said channel (6) and into the bores (14), up to the level of said recess (2), so that these form a part which is complementary to said jack (1), f) removal of the filling channel (6), g) after the filled concrete is hardened, placement of a second of the aforementioned h us (SOb) parallel to said first housing and in such a way that the jacks (1) on the second of said housing (50b) are supported by said complementary part, h) repetition of steps a) to g) until a barrier is formed consisting said plural housing (50a - 50n) and hole elements (3a - 3n).