NO334749B1 - Geobøye - Google Patents

Abstract

Geo buoy (11) comprising hull (12), mast (13), power supply and necessary electronics, the Geo buoy includes a movable, hinged lifting bracket (14) allowing moving parts of the buoy, such as mast (13), transponder (14), automatically to be moved between different positions depending on the lifting force applied to the lifting bracket (14). This enables, among other things, automatic protection of sensitive equipment when the geo buoy is lifted from the water.

Description

The present invention relates to a geobuoy as stated in the preamble to patent claim 1.

Background

In marine operations, buoys that have a mast arrangement of various types are used. It is common for these masts to contain electronic receivers and transmitters. These electronic units are placed on a mast to gain distance from the sea surface so that signals to and from the buoy can reach boats at a greater distance. Since the earth is curved, a taller mast will have a longer range than a shorter mast. Based on this simple principle, in many cases it is desirable to have the highest possible master's degree.

On most of the boats that are used to operate with such buoys, there is a limited height on the deck where the buoys are taken in and stored. If one then uses buoys on such a boat with a mast that makes the total height of the buoy exceed the total height of the deck, the mast must necessarily be reduced in height before the buoy is taken onto the deck. With very few exceptions (US patent 5,616,059), the height of the mast must be reduced manually. Since this must be done before the buoy enters the deck, this operation must be carried out while the buoy is hanging/lying outside the forward side. This is an operation that is both dangerous for the crew and takes time to perform.

On some buoys, there is also a need for a solar panel to generate electricity. On certain types of buoys, there is limited space to mount these solar panels. They are then often mounted with simple bolts so that they can be dismantled to gain access to parts of the buoy located under the solar panel, such as electronic junction boxes. In common use today, there are two variants, a type that can only be taken off or put on and a variant that is hinged in such a way that it is lifted up at one end. Both of these solutions have an element of danger in them, the one that is dismantled can be thrown around on the deck and the one that is hinged can fall back down and injure crew working under the panel.

US patent no. 5 616 059 describes a buoy with a fold-down mast where the mast is brought to an upright position through resistance from the water when the buoy is in motion. This provides a workable solution to the storage problem, but provides no protection for other equipment on the buoy.

GB 2311496 A describes a tail buoy comprising a hull with a cabin carrying a collapsible mast. The buoy contains depth measurement equipment in the form of a retractable transponder unit. Both the mast and the transponder unit are raised and lowered using hydraulic drivers that are maneuvered with control signals from a seismic vessel.

US patent no. 1376055 A describes a marking buoy with a collapsible mast arranged with a pivotable joint in the lower part of the mast. The short end of the mast carries a weight which in transport position is stored together with the mast in a protected space in the hull. When the buoy is taken off the vessel and placed on the water, the plumb line will be lowered and automatically ensure that the mast is raised in a standing position.

There is thus a need for buoys where the mast can be easily and reliably brought from an upright to a lying position when the buoys are not in use, such as for storage and transport, on water and possibly on land, and where sensitive equipment on the buoys can be effectively protected already as the buoy lifted from the water..

It is thus an aim of the present invention to provide a solution to said need.

It is a secondary purpose to provide a system to easily and reliably also protect other equipment on a buoy when it is brought from an active to a passive position, such as in connection with storage or transport.

Present invention

The above-mentioned purposes are achieved by a buoy according to the present invention as defined by patent claim 1. Preferred embodiments of the invention appear from the independent patent claims.

The present invention is a hinged lifting attachment which can also be used as a mast attachment. Single

said, this invention will cause the mast to be automatically lowered when the buoy is lifted on. For example, when the buoy is to be lifted from the sea surface onto the boat's deck, the design of the lifting fixture will cause the mast to be lowered when there is a weight load on the lifting fixture itself. The mast will then be lowered as soon as the buoy is lifted out of the water and will remain in this position as long as there is a load on the lifting attachment. In this way, the buoy can be taken onto the deck and placed where it should be with the mast lying down. As an additional possibility, a manual or automatic lock has been added so that the mast can remain in a horizontal position after the weight load (lifting force) has been taken by the lifting attachment. The automatic lock may be based on a mechanism similar to the click function of a ballpoint pen, i.e. it is alternately on, alternately off each time a new lifting force is applied to the lifting attachment after being removed. In this way, the mast can remain down after being lifted aboard and yet again be raised automatically when it is deployed again. In addition or instead, it can optionally be provided with a manual lock, such as a locking pin or the like, which an operator manually places or removes when lifting or release of the buoy.

Power supply can be in the form of cable, battery, a combination or other type of power supply. In relation to the present invention, there is nothing special about the power supply and it is therefore not discussed in more detail here. The same applies to the electronic components on the geobuoy, which can easily be "standard".

In some applications, in addition to the mast, various types of transponders are also placed on the underside of the buoy. For optimum effect, these should be placed below the lowest point on the buoy so that the transponder has free space for 360 degrees in the horizontal plane. A permanently mounted transponder in this position will be very susceptible to damage when the buoy is moved. There are different types of solutions to protect the transponder while moving the buoy. The solution that is most widespread is a steel tray that has the transponder mounted on it. This board is hinged and has a weight balance that means the transponder is hidden under the buoy. The transponder is pushed into the correct position under the buoy when the buoy is in the water and is towed forward. The force of the water hitting the hinged board will force the board down and the transponder will come into position under the buoy. As soon as the buoy loses speed and the water pressure is reduced, the transponder will tilt up into a hidden position. (Partnerplast).

According to an embodiment of the present invention with a hinged lifting attachment, the supply of lifting force to the lifting attachment can be used to protect the transponder when the buoy is to be raised from the water. By having a mechanical transmission between the lifting attachment and the transponder, we have a function that works so that the transponder will be pulled into a safe position inside the buoy or in a sleeve on the buoy when there is a weight load on the lifting attachment. When the buoy is lifted out of the water, the transponder will be pulled into a hidden position and will remain there until the buoy is placed in storage, preferably also after the lifting force has been removed from the lifting attachment. A manual or automatic lock can ensure that the transponder remains protected when the lifting force is removed from the lifting attachment. The principle mechanisms for the purpose may be similar to the locking mechanisms described in connection with the mast above, but may also be different.

When launching at sea, the transponder will be pushed out into a free position under the buoy as soon as the power is taken from the lifting attachment. The transponder will then be in the free position as soon as the buoy is on the sea, regardless of whether the buoy has speed or not. A mechanical device can be fitted which exerts a small push on the transponder, big enough to ensure that it comes into a free position on the sea and small enough so that the transponder is not damaged if it is released when the buoy is stored.

According to a further variant or embodiment, the present invention comprises a solar panel mounted on a slider so that the panel can be easily pushed aside and provide easy access to the part of the buoy which is normally covered by the solar panel. When the solar panel is pushed out, it is locked, manually or preferably automatically, so that there is no danger of it sliding back in the event of large waves. The solar panel is designed so that it is locked in its normal position when the lifting attachment is not under load, for example when the buoy is in the sea. It is also possible to use the sliding system without the lifting attachment being connected.

Functional description of various elements of the geobuoy according to the present invention Hinged lifting attachment.

Lifting attachment, device where lifting equipment is attached to the buoy, is mounted on the buoy so that the attachment itself will move between two positions, rest/production position and lifting position, when the buoy is lifted and set down. The lifting attachment returns to the rest/production position when the lifting load on the buoy/attachment is reduced. This function can work with the help of pure gravitational force, with mechanical force or hydraulic force and or a combination of these. The lifting attachment can be manually locked in both positions, both in the lifting position and in the rest/production position.

Function: Create a mechanical change that is directly dependent on whether the buoy is lifted on or not. This mechanical change can be used directly or indirectly to change functions of equipment connected to the buoy.

Automatic folding mast.

Mast mounted on the buoy. The mast is hinged and will automatically be lowered when there is a load on the lifting attachment during lifting. The mast can be attached directly to the lifting attachment or attached in connection with the lifting attachment with a mechanical transmission between the lifting attachment and the mast. The mast will rise automatically when the load on the lifting attachment is reduced, and will stand upright when there is no load on the lifting attachment. This function can work with the help of pure gravitational force, with mechanical force or hydraulic force and or a combination of these. The mast can be manually locked in both positions, both in an upright position and in a horizontal position. The mast, which is hinged either at the rear or at the front of the mast itself and is then laid down either forwards or backwards on the buoy, can and is used without connection to the lifting attachment, with or without another mechanical or hydraulic mechanism that raises or lowers the mast.

Hidden/protected transponder

Transponder, electronic equipment that either sends or receives, or both, signals underwater. The transponder can be in two positions, or in a position in between, protected or in production. In the protected position, the transponder is completely hidden inside a casing that lies within the outer limits of the buoy, i.e. inside the buoy body itself or in a casing that lies within, for example, a sled or other equipment that creates an outer boundary. In the production position, the transponder is placed so that it lies below the outer limits of the buoy and has free space for 360 degrees in the horizontal plane.

The transponder will automatically retract into a protected position when there is a load on the lifting bracket. The transponder can be attached directly to the lifting attachment or attached in connection with the lifting attachment with a mechanical transmission between the lifting attachment and transponder. The transponder will be pushed out automatically when the load on the lifting attachment is reduced, and will be protected when there is no load on the lifting attachment. This function can work with the help of pure gravitational force, with mechanical force or hydraulic force and or a combination of these. The transponder can be manually locked in both positions, both in the protected position and in the production position The transponder, which can be in two positions, or in a position in between, protected or in production, can and is used without connection to the lifting attachment, with or without another mechanical or hydraulic mechanism that moves the transponder between the two positions.

Sliding solar panel.

Solar panel that is mounted on a buoy to generate electricity. The solar panel can be in two positions, or in a position in between, open or in production. In the open position, the solar panel is attached to a sliding mechanism in the horizontal plane so that the area normally covered by the solar panel on the buoy becomes accessible. In production, the solar panel is placed on the buoy so that it is positioned appropriately for the production of electricity and with the least possible risk of damage to the panel. The sliding mechanism can be that the attachment to the solar panel slides in a groove or that the attachment is fixed in a rolling slide (kitchen drawer solution) or a combination of these.

The solar panel will automatically be pulled to the production position when there is no load on the lifting bracket. The solar panel can be attached directly to the lifting bracket or attached to the lifting bracket with a mechanical transmission between the lifting bracket and the solar panel. The solar panel can be moved to the open position when there is a load on the lifting bracket. This function can work by means of manual force, pure gravitational force, with mechanical force or hydraulic force and or a combination of these. The solar panel can be manually locked in both positions, both in the open position and in the production position. The solar panel, which can be in two positions, or in a position in between, open or in production, can and can be used without connection to the lifting bracket, with or without another mechanical or hydraulic mechanism that moves the solar panel between the two positions.

All the functions can be connected to each other or used separately, all depending on which functions are used on the buoy.

Functions described here are all used on Tailbøjer for seismic shooting in water. There are also other buoys, such as dilt floats, which can also use some or all of the functions described. There are also various other types of buoys that are used for, among other things, monitoring waves, tsunamis, meteorology, pollution and more where the described functions can be used.

It is now shown to the figures where

Figure 1 shows an embodiment of the geobuoy according to the present invention in the sea.

Figure 2 shows the geobuoy from Figure 1 in the process of being lifted from the sea.

Figure 3 shows the geobuoy from figures 1 and 2 lifted up from the sea.

Figure 4 shows the geobuoy from figures 1-3 on the deck.

Figure 5 shows a variant of the bend shown in Figures 1-4 on the deck.

Figure 6 shows another embodiment of a geobuoy according to the present invention in the sea.

Figure 7 shows the geobuoy from Figure 6 lifted up from the sea.

Figure 8 shows another variant of a geobuoy according to the present invention in the sea.

Figure 9 shows the geobuoy from Figure 8 on the deck.

Figure 1 shows a geobuoy 11 according to the present invention in the sea. The buoy is active, that is to say that the mast 13 is upright in order to be able to transmit signals to and from the outside world as best as possible. The mast 13 is shown attached to a separate, hinged lifting attachment which is shown here in a horizontal position.

In Figure 2, the same buoy has been connected to a lifting wire 15 or the like which pulls on the lifting attachment 14 and causes it to start moving from its horizontal position more in the direction of vertical positioning. This necessarily causes the mast to move from a vertical position to a horizontal position.

Reference is now made to Figure 3. Here the buoy is lifted free of the water and the lifting attachment 14 is thus vertical and the mast 13 approximately horizontal or parallel to the longitudinal axis of the geobuoy. It is not important that the geobuoy or the mast in this condition is exactly horizontal, what is important is that the mast is laid down and approximately parallel to the axis of the geobuoy. From the mechanism shown, it will be understood that the lifting attachment 14 is raised to an approximately vertical position already before significant lifting force has been applied and that the mast is correspondingly lowered already before the buoy is raised from the water. However, it is not a prerequisite for the present invention that there is such a direct joint assembly of mast and lifting attachment, only that they are connected to each other. There is thus no requirement for the mast to be (completely) lowered already when the lift begins.

Figure 4 shows the geobuoy placed on a deck or in a warehouse. Here the lifting wire 15 has been removed, but the mast remains in the lowered position due to a manual or automatic locking mechanism, referred to as the first locking mechanism, which is not shown. This can be realized in many ways, but a preferred mechanism is an automatic lock which engages with one lift in the lifting mechanism 14 and which again automatically disengages with the next lift in the lifting mechanism. Thereby, the mast will remain down when the geobuoy is placed on deck, but will be raised again after being lifted again. Optionally, as an alternative or in addition, it can be provided with a manual lock which ensures that the mast remains down until the manual lock is unlocked again. Figure 5 shows a variant of the geobuoy shown in figures 1-4 in the same position as figure 4, that is on deck and with the mast down. The only difference is that the mast attachment is located in a lowered area of the buoy so that the mast comes closer to the buoy when it is lowered and is thereby even better protected. Figure 6 shows a different embodiment of a geobuoy according to the present invention than that shown in figures 1-5. The difference is that this geobuoy is also equipped with a transponder 16. In Figure 6, the geobuoy in the sea is in an active position, that is, with the mast 13 upright and with the transponder lowered to below the lower level of the hull 12. The transponder 16 is lowered from a well or a casing 17 which can be inside the hull 12 or lie outside the hull 12. A line mechanism 18 is shown which connects the transponder to the lifting attachment 14. When the lifting attachment 14 is raised during lifting from a horizontal to a vertical position, ref. Figure 7, the line mechanism 18 pulls the transponder 16 into the well or casing 17 so that the transponder is protected against mechanical influences from the outside when it is lifted from the water. In the same or similar way as for the mast, the transponder can be locked in a protected position with a locking mechanism referred to as the second locking mechanism, so that it remains protected even after the lifting force is removed from the lifting attachment 14.

It should be emphasized that the line mechanism shown is only one way among several to connect the transponder to the lifting attachment, and that many other mechanical connections are conceivable within the scope of the invention. With the solution shown, one common locking mechanism on the lifting attachment 14 can ensure that both mast 13 and transponder 16 remain protected, that is to say that the first and second locking mechanisms are in practice one and the same locking mechanism in this particular embodiment. The required lifting force on the lifting attachment (14) to bring the transponder (16) to a passive, protected position is usually less than the lifting force for the buoy.

Figure 8 shows further equipment in connection with a geobuoy 11 according to the present invention. The geobuoy 11 is again shown in its active position in the sea. Shown here is a solar panel 18 which is displaceable horizontally, but which is locked in place by the lifting attachment 14 via a locking mechanism 19 so long the lifting attachment is unburdened by lifting forces, that is in its horizontal position. In figure 9, the same variant of the geobuoy is shown with the mast down, whereby the solar panel is freed and can be pulled out and locked in the service position.

It is not shown in connection with the figures, but it is natural that the lifting attachment 14, by means of spring loading or in some other way, automatically seeks a horizontal position (upright mast) when it is unburdened by lifting forces, without necessarily being locked in this position.

The illustrations are illustrative only. Dimensions may be drawn to bring out details clearly and distinctly. The shape of the equipment can vary significantly, as can the geobuoy itself, which can have different external shapes.

As already pointed out, the mast (13) can be moved from an upright position) to a protected position by applying a force which is less than the lifting force of the geobuoy, but at most equal to the lifting force of the geobuoy (11).

The connection between the lifting bracket (14) and the mast (13) is preferably a purely mechanical connection, but does not have to be an assembly as shown in the figures.

Claims (15)

1. Geobuoy (11) comprising hull (12), mast (13), power supply and necessary electronics, characterized in that it comprises a movable, hinged lifting attachment (14) which allows movable parts on the buoy to be automatically moved between different positions depending on lifting force applied to the lifting attachment (14). 2. Geobuoy in accordance with patent claim 1, characterized in that the lifting attachment (14) is connected to the mast (13) so that the mast (13) is moved from an upright position in the absence of lifting force on the lifting attachment (14) to a protected position when a force is applied maximum equal to the lifting force of the geobuoy (11). 3. Geobuoy in accordance with patent claim 2, characterized in that the protected position is a position where the axis of the mast (13) is parallel to the longitudinal axis of the geobuoy. 4. Geobuoy in accordance with patent claim 2, characterized in that the required lifting force on the lifting attachment (14) to bring the mast (13) to a protected position is less than the lifting force for the buoy. 5. Geobuoy in accordance with patent claim 2, characterized in that the geobuoy (11) is equipped with a first locking mechanism which allows the mast to remain in a protected position when the lifting force on the lifting attachment ceases. 6. Geobuoy in accordance with patent claim 5, characterized in that the first locking mechanism is designed to be disconnected when a new lifting force is applied to the lifting attachment (14). 7. Geobuoy in accordance with patent claim 2, characterized in that the connection between lifting attachment (14) and mast (13) is a purely mechanical connection. 8. Geobuoy in accordance with patent claim 7, characterized in that the mast (13) is mounted on the lifting bracket (14), and that the lifting bracket (14) is arranged to be rotated approximately 90 degrees when lifting the geobuoy (11). 9. Geobuoy in accordance with patent claim 1, characterized in that it comprises a transponder (16) and that the lifting attachment is connected to the transponder (16) so that it is moved from an active, unprotected position in the absence of lifting force on the lifting attachment (14) to a passive , protected position by supplying a lifting force on the lifting attachment (14) maximally equal to the lifting force for the buoy. 10. Geobuoy in accordance with patent claim 9, characterized in that the passive, protected position is a position where the transponder (16) is physically, completely or partially enclosed by a protective casing (17). 11. Geobuoy in accordance with patent claim 9, characterized in that the required lifting force on the lifting attachment (14) to bring the transponder (16) to a passive, protected position is less than the lifting force for the buoy. 12. Geobuoy in accordance with patent claim 9, characterized in that the geobuoy is equipped with a second locking mechanism which allows the transponder (16) to remain in a passive, protected position when the lifting force on the lifting attachment ceases. 13. Geobuoy in accordance with patent claim 12, characterized in that the second locking mechanism is arranged to be disconnected when a new lifting force is applied to the lifting attachment (14). 14. Geobuoy in accordance with patent claim 9, characterized in that the connection between lifting attachment (14) and transponder (16) is a purely mechanical connection. 15. Geobuoy in accordance with patent claim 1, characterized in that the power supply comprises a solar cell panel (18) which is movable from an active position to a passive, protected position and that the solar cell panel (18) is locked in an active position when there is an absence of lifting force on the lifting bracket (14).