NO20101597A1 - Buoyancy - Google Patents

Abstract

It is referred to as a construction for a pump system wherein one end of a hose is led down to a bottom area for pumping solid particles in admixture with water by means of a pumping means, and it is characterized by the hose comprising one or more buoyancy means adapted to hold the snake mainly in an upright position in the sea. The structure can be used in conjunction with a fish farm in the sea for the pumping of submerged fores, faeces and dead marine organisms, especially fish, or in a pumping system and system for pumping waste from a seabed, such as mud and the like. The invention also relates to a new construction of a float, as well as applications.

Description

The present invention relates to the construction of a buoyancy body (a float) for a pumping system including a hose and pumping device as stated in the introduction in the following claim 1, for pumping up solid and liquid waste.

The invention also relates to a construction of a buoyant body, as well as an application of the inventions.

In particular, the invention is concerned with the system used to suck up sinking remains, faeces and dead marine organisms (especially fish) inside a cage in the sea. But it can be used in all situations where there is a need to pump up waste.

With solid and liquid waste, one thinks in particular of the aforementioned remains (such as pellets), faeces and dead fish, but also of all types of waste that, for example, may lie on the seabed, such as sludge and other solid particles/objects.

With marine organisms, one thinks in particular of fish, but there can be others such as crustaceans or the like.

In addition to being used in a cage, it can therefore be used in connection with a hose which, with the help of a pump system, carries sludge from a seabed up to the surface for further treatment.

In this connection, reference is made to Figure 1, which shows a known system for sucking up waste from the bottom of a breeding pen.

The cage is shown at 10, and comprises an annular frame 12 to which is suspended an annular cage mesh (or of dense fabric) 14. The bottom part of the cage is formed by a funnel-shaped groove section 16. Inside the closed cage, the swimming farmed fish are stored 17. Inside and at the bottom of in the cage's funnel section 16, there is arranged a tight upward-turning collection funnel 20 in which sinking waste is collected and enriched.

Down into the bottom of this funnel is stretched the end 22 of a hose or a pipe 20 which then extends up to the surface and slopes further at 24 until a collection box 26 where the mixture of waste and water is separated by the water being filtered off and flowing back into the sea through pipe 27, while the solid waste and any sludge is carried on to other necessary treatment or destruction at 29.

The actual pumping up of the waste mixed with water takes place by a hose 30 for pumping compressed air 25 (see Figure 3) being led down into the cage and connected to the hose/pipe 20 adjacent to the suction end 22. The air is pumped into the hose 20 into the hose through an ejector nozzle 23 and the air in the form of the droplets 25, creates an upward ejector effect so that water and waste are sucked into the bottom 22 and then lifted up through the hose and carried over to the sieve box 26 where the water is released back into the sea and the solid waste is further handled in a responsible manner.

At the same time, this means that the hose is tensioned 20 up to its vertical position as figure 1 shows. When the injection of air stops, the hose with the connected ejector 23 and hose system 30 will partially sink down and fold or fold together at the bottom of the cage.

This has a major disadvantage when pumping is to start up again. When the hose 20 begins to fill with air during the next pumping up of waste, large movements occur in the hose 20 and its air pump system, which can cause major damage. In addition, a good deal of pumping energy is used to raise the hose from the folded position.

It is the main purpose of the invention to construct a new system which will completely eliminate these disadvantages of the current system.

The invention is characterized by the hose comprising one or more buoyancy devices designed to keep the hose mainly in an upright position in the sea.

The following features are preferred:

-the buoyancy device is a float connected to the hose.

-the buoyancy device is a combined piece of pipe with an integrated float which is arranged in a ring around the piece of pipe, which piece of pipe is connected/joined onto the hose at a suitable height above the bottom. - the outside of the float 44 is designed with rounded edges and corners so that the float cannot catch on ropes and the like and cause damage. -the pump is an air ejector, where an air hose is arranged to be connected to the hose adjacent to the lower end, and by injecting air a water flow is created for pumping up the waste through the hose.

The floating body is characterized by a combined piece of pipe with a float, where the float is arranged in a ring around the piece of pipe.

Preferably are:

- the float arranged around the central part of the pipe.

- the float defined by a jacket arranged around the tube, and the jacket defines together with the tube one or more chambers with a gas/air filling, - the float a floating element with a floating foam, or a material with a lower specific gravity than water, such as a cork material or a floating foam such as Styrofoam material.

The gas can be chosen from air, nitrogen, or various noble gases such as argon, or mixtures of these.

According to the invention, construction is used in a breeding cage in the sea for pumping up sinking remains, faeces and dead marine organisms, especially fish; or in a pumping system and system for pumping up waste from a seabed, such as sludge and the like.

The float is designed with milled grooves for hose clamps, milled edges to prevent wear from flat hoses etc. The buoyancy of the float should be adapted to the weight of the hose system.

The advantages of the present invention are many:

Firstly, the hose system in the pump remains upright in the sea at all times.

This leads to the great advantage that the propellant during pumping, which is usually air, has an upward effect immediately as soon as the pump starts, and without requiring energy to raise the hose system which is partially folded.

The advantages of are thus that the hoses are not folded and more or less sunk down at the bottom of the cage groove when pumping starts, and the system does not experience the strong upward forces that affect the hoses and pump head (23) in such a starting phase when supplying the air.

Such movements of the hoses and pump system can, in exposed locations, lead to major wear and tear and damage to the groove and hose system.

By standing the pump upright, one avoids that the hoses that supply the air do not act as a barbell on the pump head and it gets an incorrect angle in relation to the bottom of the net, which can cause the fish to lie down incorrectly in relation to the entrance to the pump (which may be designed like a sombrero).

By having the pump system stand upright in the center of the billet, it is easier to avoid other equipment such as biomass frame, underwater camera, sensors etc. filters and settles into the hoses and ropes of the cage system.

Several things that can be mentioned are that there are often different lengths of the lifting systems in the smolt cages and in the food fish pens since these can have different depths. With the present invention, the buoyancy body/float can be located completely in the water crust or below, and keep the hose 20 upright in the sea.

The float can be placed anywhere from just below the surface to further down the billet.

The invention shall be explained in more detail by reference to the following figures, in which:

Figure 1 shows a system for pumping according to known solutions.

Figure 2 shows a similar system but where the invention is applied. Figure 3 shows a longitudinal cross-section of the buoyancy element according to the invention inserted into a hose/pipe 20.

Figure 4 shows a perspective view of the inventive buoyancy body.

Figure 5 a cross-section taken along the line X -X in Figure 3.

Figure 1 was discussed earlier as representative of the state of the art. Figure 2, which is a slightly enlarged section from Figure 1, shows that a buoyancy body 40 is connected to the top of the hose 20, which is shown in detail in Figure 3.

This rearing body which includes an air-filled body or tank 40 which is connected to the hose 20. In general, it can be a hollow body which is attached to and outside of or wrapping around the hose 20.

However, according to a specific preferred solution, and which is shown in Figures 3-5, the buoyancy body is designed as an independent section comprising a tube 42 to which an annular float body 44 is integrated. The tube 42 extends through the float body 44. On the outside, the float body 44 is designed with rounded edges and corners so that the float cannot catch on ropes and the like inside the cage and cause damage.

The construction of the float element 44 is shown most clearly in the longitudinal section in figure 3 and in the cross section in figure 5. The element comprises a jacket 41 which is dressed or arranged on the outside and around the pipe. Between the inner wall of the jacket 42 and the outer wall of the tube, an annular chamber 43 is then established which is filled with a gas, particularly air. The outside of the float element 44 and the transitions to the cover 42 are correspondingly designed with rounded edges and corners.

To ensure buoyancy, the chamber 43 can be filled with a floating foam, which is beneficial if the body wall 44 punctures and water flows into the chamber. The figures show a float construction with the float body and two protruding pipe ends 46,48. Each of these two pipe fittings has approximately the same dimension (diameter) as the hose 20, so that the main hose 20 is cut in two, and the respective ends 20A, 20B are threaded on the outside of the aforementioned pipe fittings 46 and 48 respectively, and attached to the pipe fittings using hose clamps (not shown) or other suitable fasteners. The entire buoyancy body thus forms an integral part of the hose system. Figures 3 and 4 also show the mounting flanges 50,52 and 54,56 which are designed on the outside of the pipe ends 46 and 48, respectively.

Figure 4 shows possible practical dimensions for a float according to the invention. The entire construction can have a total length of about 105 cm, of which the length of the float unit can be 55 cm and, each pipe connection has a diameter of 20 cm and a length of 25 cm, and the total width can be equal to 30 cm. The chamber will then have a volume of approximately 20 litres.

The floating element which is designed to be inserted as part of a hose or pipe can be made of plastic material of the type PE plastic (polyethylene) or other suitable material. It can be produced by threading around a pipe section (e.g. of a given 1.05 meters) which is mounted in a holder and the chamber-forming jacket onto the pipe and welding it so that there are smooth transitions and no sharp edges.

Claims (11)

1. Construction for a pumping system where one end of a hose is led down to a bottom area for pumping up solid particles in a mixture with water by means of a pumping device, characterized in that the hose comprises one or more buoyancy devices designed to keep the hose mainly in a upright position in the sea. 2. Construction in accordance with claim 1, characterized in that the buoyancy device is a float connected to the hose. 3. Construction in accordance with one of the preceding requirements, characterized in that the buoyancy device is a combined piece of pipe with an integrated float which is arranged in a ring shape around the piece of pipe, and which comprises one or more gas/air-filled chambers or a floating body with a specific gravity lower than water , which piece of pipe is connected/joined onto the hose at a suitable height above the bottom. 4. Construction in accordance with one of the preceding requirements, characterized in that the outside of the float 44 is designed with rounded edges and corners so that the float cannot hook into ropes and the like and cause damage. 5. Construction in accordance with one of the preceding requirements, characterized in that the pump is an air ejector, where an air hose is arranged to be connected to the hose adjacent to the lower end, and by injecting air a water flow is created for pumping up the waste through the hose . 6. Device for buoyancy body, characterized by a combined pipe piece with a float, where the float is arranged in a ring shape around the pipe piece. 7. Device in accordance with claim 6, characterized in that the float is arranged around the central part of the pipe. 8. Device in accordance with claims 6-7, characterized in that the float is defined by a jacket which is arranged around the pipe, and the jacket together with the pipe defines one or more chambers with gas/l uft-fy 11 in ng. 9. Device in accordance with one of claims 6-8, characterized in that the float is a floating element with a floating foam, or a material with a lower specific gravity than water, such as a cork material or a Styrofoam material. 10. Application of construction according to the preceding claims, in a breeding cage in the sea for pumping up sinking remains, faeces and dead marine organisms, especially fish. 11. Application of construction according to the preceding claims, in a pumping system and system for pumping up waste from a seabed, such as sludge and the like.