BE1023072B1 - System of storage and electric power generation in marine environment - Google Patents

Abstract

A system for storing and producing electrical energy in a marine environment in which one or more weights are lowered and then raised from a high position to a low position, using at least one cable (115) connected to a barge or a platform (110). The barge comprises a generator / motor (113) actuated by or actuating said cable. The weights (107,108) are secured to a partially floating element (106, itself connected by a retaining cable (105) to a surface floating element (101) which is provided with means for varying the length of said cable retaining element (105), the element (106) comprising a volume of compressible gas as a function of the surrounding pressure.

Description

STORAGE SYSTEM AND ELECTRIC POWER GENERATION IN A MARINE ENVIRONMENT

The present invention proposes a system for storing and producing energy in an aquatic environment, in particular in a marine environment.

The patent document WO 2014/160522 describes the prior art and proposes such a system comprising a platform and a set of weights deployed on a seabed and each ballast being able to be moved from one depth to another depth by a winch present on the platform. This system comprises a means for locating and gripping the ballast controlled remotely independent or connected to the winch system. According to one embodiment, the ballast may comprise a volume of gas that can vary under the action of valves, possibly remote controlled, and thus be partially self-floating. On a large scale, the platform needed to store ballast is however of such size that wind and surface currents will generate very high anchoring or stabilization costs.

The present invention proposes among other things to avoid this disadvantage.

According to the invention the ballasts in the high position of energy storage are stabilized to a depth such that the effect of wind and currents on the system is greatly reduced.

The solution comprises the realization of a system in which at least one float carrying the weights is subdivided into at least two parts connected by a retaining cable, the largest of which comprises the submerged ballast or weights and has the advantage of 'be located several tens of meters below the surface (where the current is less strong). This float will be designated USPV in the remainder of this description (Variable Depth Suspension Unit).

The submerged portion of the float comprises a volume of gas in contact with the surrounding pressure, possibly provided in a flexible envelope. When the ballast or weights are unhooked (one by one), to prevent the submerged part of the float from rising and catching wind or surface current, the volume of gas will be reduced under the effect of the surrounding pressure, because will be lowered to a greater depth via the restraining cable which will be partially unlocked, and thus this portion of the float will provide a lower upward force and which will be adapted to the downward force, also lower, of the ballast (s). remaining.

The volume of gas can be contained in a balloon or "parachute" or in the upper part of a rigid enclosure, but in contact with the water via orifices located under the cavity. For example, the surface float portion may have a volume of 100 M3. The submerged portion of the float may have a volume of 300m3. The weight of a ballast may be of the order of 100 tons. The length of the main cable will be determined by the depth of the seabed, for example, 4,000 meters. The invention is further described below in the form of various embodiments and with reference to the figures in which:

Figure 1 shows several USPV whose load level is different and for which the depth of the parachute (balloon or flexible envelope of the immersed portion of the float) is different.

Figure 2 shows a means of securing several USPV via a beam (201) attached to each of the USPV via a cable or a ball joint system.

Figure 3 shows another way to secure the USPV, positioning them on a single barge (301).

Figure 4 shows one way of maintaining the USPV (s) in a given position via anchoring cables.

Figure 5 shows another way of maintaining the USPV (s) in a given position via propeller thrusters.

Figure 6 shows the different load levels of the USPV and ballast position on the hoist.

Figures 7a and 7b show a variant in which the USPV and the hoist are mounted on a barge.

Figure 8 shows a detailed view of a ballast hanging from a hook via a hook cable.

Figure 9 shows different positions and configurations of ballast.

Figure 10 shows several variants for the submerged float according to the invention.

Figure 11 shows the lifting parachute as depicted in Figure 1 and on the right a ballast partially filled with water and partially filled with a gas.

Figure 12 shows another way to secure the USPV together.

Figure 13 shows a structure comprising a plurality of ballast connected to a barge with several winches or pulleys.

FIG. 14 represents a variant of the structure of FIG. 13 in which each ballast comprises a flexible envelope forming a bladder or parachute.

In more detail, Figure 1 shows several USPV whose load level is different and for which the depth of the parachute (balloon or flexible envelope) is different. The float or barge (101) contains a capstan or pulley (102) connected by a cable (105), on one side to the parachute (106) and on the other side to a mass (103) to balance the loads . Alternatively, the float or barge (101) may include a winch to change the length of the tether to the pleat of the capstan or pulley. The parachute makes it possible to suspend a plurality of weights (107 and 108) of which at least one can not be detached (107) in order to maintain a load permanently regardless of the volume level (and therefore the depth) of the parachute.

Each ballast is suspended from the parachute by a hook and a cable (109) whose length can advantageously vary from one ballast to another so that they are not suspended at the same height and do not collide. Near the USPV, there is a barge on which are one or more hoists, or winches or pulley lifts to descend and then up one by one the ballast from the USPV to the bottom of the sea and respectively release or store electricity via a generator / electric motor connected to the hoist via driving pulleys or connected to the winches or to the pulley elevator.

Figure 1 shows the barge (110), the cable of a double hoist (115), a set of driving pulleys (112), a set of reduction pulleys (111), the electric generator motor (113) is connected to the pulleys motor, it can be connected to pulleys via gear reducer (not shown in this view)

The sea level is represented by 104. The engine / generator (113) and the barge (110) are connected to the electrical network via a submarine electrical cable represented by 114.

The cable (115) of the hoist is connected to a hook (117) which can be moved horizontally using a ROV (116) (ROV = remotely operated vehicle or underwater robot).

In the example of the double hoist, each of the two hooks is connected to an ROV (the second hook is not shown in Figure 1).

Another independent ROV can be used to facilitate the hooking and unhooking of the weights since the USPV (119)

The barge 110 may be anchored to the seabed or maintained by one or more propeller thrusters. If anchored, it can be moved horizontally by connecting the anchor cables to winches that can be controlled so that the barge is positioned near the USPV being loaded or unloaded or close to the service area. storage on the seabed.

USPVs can be autonomous or interconnected in many different ways.

FIG. 2 represents a means of securing several USPVs via a beam (201) fixed to each of the USPVs via a cable or a ball joint (not shown on the picture)

This figure also shows a system for multiplying the force of the cable (202) between the float and the counterweight (103) via a set of pulleys (203). This provides an advantage in that the distance to be traveled by the counterweight can be reduced compared to the depth variation that the parachute must be able to undergo (106).

Figure 3 shows another way to secure the USPV, positioning them on a single barge (301). In this figure, only 2 USPVs are represented.

FIG. 4 shows a way of maintaining the USPV (s) in a given position, here, via anchoring cables 401 (the anchor is not shown in the view)

FIG. 5 represents another way of maintaining the USPV (s) in a given position, here, via propeller thrusters (501)

Figure 6 shows the different load levels of the USPV and ballast position on the hoist.

Position 606 shows a USPV loaded with 3 moving weights and 1 fixed ballast, the parachute has maximum volume and is positioned at a shallow depth.

Position 607 shows a USPV loaded with 2 moving weights and 1 fixed ballast, the parachute is then positioned at a slightly greater depth so that the higher pressure reduces the volume and the Archimedes thrust exerted by the prachute, so that she has to remember only 2 weights.

The position 608 shows a USPV loaded with a single moving ballast. The position 603 shows an empty USPV without any moving ballast and thus comprising only a fixed ballast. This fixed ballast prevents the parachute from rising because even at a greater depth, there remains a residual volume that may not be offset by the relative weight of the vacuum parachute membrane.

The hook 601 is loaded with a ballast while the hook 602 (the other hook of the double hoist) is not loaded. Whether the platform operates in storage mode or destocking (respectively successive rise or fall of the weights one by one), there is always one of the hooks of the double hoist loaded and another not loaded.

Position 604 shows weights stored on the seabed (605).

FIGS. 7a and 7b show a variant in which the USPVs (706) and the hoist (707) are mounted on the same floating structure (here a barge) 701 seen from the side and 702 seen from above. The hoist can be mounted on rails (708)

The barge (702) can be anchored via one or more anchor lines (703), one or more anchors (704) and one or more winches (705)

FIG. 8 shows a detailed view of a ballast (809) suspended from a hook (806) via a hook cable (805) attached to two ballast support points so that the center of gravity of the ballast is located between the two points, in order to maintain the ballast in horizontal position. An empennage (808) equivalent to those found on the torpedoes thus allows the ballast to face the direction of the horizontal current and thus minimize the hydrodynamic friction force of the current and thus reduce the cost of maintaining USPVs over the same area (whether thrusters or anchor cable).

At least two loops (807) of hooking are provided to hang the hooks of the hoist: one at the front (for upward movements) and the other at the back (for downward movements). These loops are advantageously constituted by a cable (for example drawn stainless steel) provided with floats (803) to maintain suspension loops above the ballast and thus facilitate the attachment operations especially when the ballast rest on the bottom marine.

They are connected to the ballast by a small cable (802) to facilitate the hooking and unhooking operations and facilitate the possible work of the auxiliary ROV (119 in Figure 1)

Transmitters of light signals (809, 810) or sonar (811) or other type of wave are provided and arranged in different locations of the ballast or hooks, to facilitate the operations of hooking / unhooking, especially if those They are automated.

Figure 9 shows different positions of the weights.

The position 901 represents a ballast attached to a parachute (high point position) close to the surface, it is horizontal in order to limit the hydrodynamic friction force of the current. The position 902 represents a ballast in the descent phase, in this case the ballast causes the hook of the hoist to be down. The position 903 represents a ballast being deposited on the seabed.

Position 904 represents a ballast laid horizontally on the seabed, just after its arrival (descent), the hook of the hoist is still attached to the lower handle.

Position 905 represents a weight placed horizontally on the seabed, just before it is reassembled, the hook of the hoist is hooked to the upper loop.

The position 906 represents a ballast in the ascending phase, the front part of the ballast is therefore positioned above the rear part (provided with the empennage)

Figure 10 shows several variants:

A valve (1001) can be opened remotely or automatically, it can release a possible surplus gas and thus overcome operational hazards, especially if the parachute was to rise more than expected (for example because heating of the gas contained inside) and thus limit the risk of the parachute rising abruptly to the surface.

A flexible duct (1001) can connect the parachute to a compressor (1004) itself provided with a possible buffer tank (1003) to increase or reduce the amount of air in the parachute. This device also makes it possible to rebalance the systems in the event of unforeseen circumstances. Or to temporarily rebalance the system for example when the parachute is raised to a higher position and the air contained is cooled. This air will warm up with the ambient temperature and a change in the amount of air contained in the parachute may be desirable, although the variation of the depth may also play this role.

Another way to accelerate the heating of the gas contained in the parachute, for example just after raising the level of a parachute (expansion = cooling) is to inject a quantity of heat via an electrical resistance (1009) connected via a electric cable (1006) to a battery (1005) or any other source of electricity.

A safety device makes it possible to rapidly increase the floating power of the USPV, it comprises an auxiliary parachute (1007) partly filled with a gas and fixed by a cable (1008) to the main parachute. This parachute can be released in a remotely controlled manner (control unit 1009) or automatic if necessary, when the USPV initiates a too great descent and for example when the upper float reaches a medium level of immersion too important. By releasing this parachute, this one will go up and see its volume increase, it will thus be able to generate a surge of archimedes superior and to compensate a possible imbalance.

In Figure 11 are shown to the left, the lifting parachute as described in Figure 1 (106) and to the right a ballast partially filled with water and partially filled with a gas.

This ballast plays the same role as the parachute, its power is going to increase when the depth of the ballast will be reduced and vice versa.

The change in the amount of water can be done automatically since the ballast is pierced with one or more orifices () allowing the water to enter and compress the gas bag when the ballast is lowered. It can also be done in a controlled manner by injecting gas or by pumping or injecting water in a controlled manner via flexible hoses, compressors, pumps and valves not shown in the figure. The injection of gas allows then if necessary to modify the floating power without modifying the depth. In the same way, gas can be injected into the parachute for the same function.

FIG. 12 represents another way of joining the USPVs to each other. In this case, they are connected by a cable (1203) via the upper float this float can be rigid (as shown in Figure 1, 101) or flexible, ie with a parachute as shown in this figure (120 or 1202). The set of USPVs thus fixed to one another can also be anchored via one or more anchoring cables (401), the parachutes constituting the upper floats can have a volume adapted to take all the forces to which they can these forces may be different depending on whether it is a USPV connected only to other USPVs or a USPV also connected to an anchor cable.

Figure 13 shows a barge 1301 comprising several winches (or pulleys) 1302 connected to as many attachment cables (1303) to support a structure 1304 comprising a plurality of ballast (whose number may be different from the number of cables 1303). The ballast includes one or more water inlet and outlet ports (1306) and at least one compressed gas supply line and / or outlet (1308). The device also includes cables for hanging weights (1307) the number of attachment points of these weights and / or the ballast number may be different from the number of ballast and also different from the number of cable 1303.

Figure 14 shows a variant of Figure 13, the ballast are housed in a structure 1401 (possibly compartmentalized) in which there is one or more bladders (or parachute) 103 themselves connected to compressed gas conduits. In this variant, each compartment also includes an orifice 1404.

It will be understood that the device may comprise a plurality of platforms "hoists" and a plurality of hoists (or double hoists) can be positioned on a single barge.

The number of weights per USPV is given in the figures by way of example but is not limiting. Only one ballast or a much larger number can be stored by USPV. The invention has been illustrated essentially in a "double hoist" mode but other equivalent lifting systems can be envisaged (lifts, driving pulleys, capstan, etc.).

The hooks can be fully automatic closing or remotely controlled, if necessary, for added security.

In all variants, the USPVs can be connected by various electrical, hydraulic and / or pneumatic connections.

Claims (16)

Claims: 1. System for storing and producing electrical energy in a marine environment by gravitational effect in which one or more weights are lowered and then raised from a high position to a low position, using at least one cable (115 ) connected to a surface floating main element (110), such as a barge or a platform, comprising a generator / motor (113) actuated by or actuating said cable, characterized in that said ballasts (107, 108) are capable of to be stabilized in a raised position at a determined depth by being secured, to a partially floating element (106) at said depth, itself connected by a retaining cable (105) to a surface floating secondary element (101) which is provided with means for varying the length of said restraining cable (105), the partially floating member (106) comprising a volume of compressible gas as a function of the surrounding pressure. 2. System according to claim 1 wherein the volume of gas is delimited by a flexible wall. 3. System according to any one of the preceding claims wherein there are several partially floating elements (106) with secondary floating elements (101). 4. System according to any one of the preceding claims wherein the surface floating element (110) is a hoist barge. 5. System according to the preceding claim wherein there are several hoists (111). 6. System according to any one of the preceding claims wherein the various partially floating elements (106) are secured to each other. 7. System according to any one of the preceding claims wherein the various floating elements at the surface are secured to each other. 8. System according to any one of the preceding claims wherein the retaining cable (105) can be unwound over a length ranging from 5 to 150 meters, preferably from 10 to 100 meters. 9. System according to any one of the preceding claims wherein the weights are solidarisable, separable from the partially floating element by hooking-stall. 10. System according to the preceding claim wherein the hooking - stall is by an independent submarine means (119), such as a robot. 11. System according to any one of the preceding claims wherein there are several partially floating elements (106) and the retaining cables are unwound at different lengths. The system of claims 1 and 3 to 11 wherein there is one or a plurality of ballasts (1304) with water inlet and outlet (1306). 13. System according to the preceding claim wherein the ballasts are provided with at least one supply duct and / or compressed gas outlet (1308). 14. The system of claim 12 wherein the ballast comprises bladders (1403) themselves connected to compressed gas conduits. 15. System for storing and producing electrical energy in a water environment by gravitational effect in which one or more weights are lowered and then raised from a high position to a low position, using at least one cable (115). ) connected to a floating element on the surface (110), such as a barge or a platform, comprising a generator / motor actuated by or actuating said cable, characterized in that said ballasts are capable of being stabilized in the raised position at a determined depth by being secured to a float, said float comprising a partially floating element (106) at said depth, itself connected by a retaining cable (105) to a second surface floating element (101) which is provided with means for varying the length of said restraining cable (105), the partially floating element comprising a volume of compressible gas depending on the surrounding pressure. 16. A marine electrical power storage and production system comprising - a barge or platform (110) provided with means (111) for unwinding / winding a main cable (115) to which a ballast (108) may be hooked or unhooked, to a depth greater than 200 meters, said means cooperating with a motor coupled to an electric power generator (112, 113), - a float comprising two parts, one on the surface (101) and the other (106), being larger, being immersed, the two parts of said float being connected by a retaining cable (105), the submerged portion carrying one or more weights (107, 108) and being situated at a depth between 10 and 150 meters, a volume of gas contained in the submerged portion of the float likely to vary under the effect of the surrounding pressure, means (102) for varying the length of said retaining cable of said float, - a means of reversible transfer of ballast of the party e immersed said float at a submerged end of the main cable, - means (119) for hooking and unhooking ballast at the bottom of the marine environment.