NO312271B1 - Device and method of feeding fish - Google Patents

Description

The present invention relates to a device and a method for feeding fish, according to the preamble in the independent claims 1, 10, 13 and 14.

In the currently known devices for feeding fish that use a preferably funnel-shaped collection device for collecting unused (uneaten) feed and faeces, this is carried in a hose up to the surface for registration, where it is possibly also cleaned of sludge and faeces and recycled along with new lining through another hose. The feed is supplied from a feeding point at a height above the collection device, either above or below the water surface, and then sinks down until it is eaten by the fish, or possibly collected at the bottom of the collection device if it is not eaten. The feed typically consists of pellets of various sizes, and the pellets will increasingly dissolve in water and deteriorate with increasing residence time in the water.

The above-mentioned feeding devices are typically developed for feeding fish in the salmon family, and fish of this type easily take to food, also in and near the surface. However, there has been an increasing focus on bottom-associated species such as catfish, turbot and especially halibut. Unlike the salmon, the latter needs plenty of time to complete a meal. In addition, halibut in cages form a strict hierarchy where the largest individuals (females) easily lead to a suboptimal intake of feed for the smaller individuals (males), and that there will be large fluctuations in appetite over time. A lining controlled by the fish's appetite therefore offers clear advantages in farming.

In order to adapt the lining device to the above-mentioned bottom-associated species, as well as to avoid high surface temperatures, algae, jellyfish etc., it is desirable to lower the lining point. The known technique places limitations on how deep the lining can take place, since the lining will dissolve and deteriorate if it is transported over long distances up to the surface in a hose together with water, and thus exposed to the water over a longer period of time. If the distance between the lining and collection is too great, part of the feed could also be carried away by underwater currents without being collected in the collection device, with the negative consequences this has for the environment around the cage, and that the lost feed will not least amount to a financial loss. Pumping the liner over long distances up to the surface will also require a lot of energy, and the plant could become more complicated, and thus more expensive to produce.

As examples of the above-mentioned known technique can be mentioned WO 91/15115, NO 175662, as well as the lining device applied for today produces under the name

"ECOFEED".

In order to reduce or eliminate the above-mentioned and other disadvantages, according to the present invention, a device and a method for feeding fish have been provided which are respectively characterized by those specified in the characteristics of the independent claims 1, 10, 13 and 14 traits. Advantageous embodiments are set forth in the dependent claims.

The device according to the present invention is described in more detail below, with reference to the accompanying drawings, where;

figure 1 shows a first embodiment of the device according to the present invention, seen from the side,

figure 2 shows a first detailed section of the device shown in figure 1, and seen from the side,

figure 3 shows a second detailed section of the device shown in figure 1, and seen from the side,

figure 4 shows a second embodiment of the device according to the present invention, seen from the side,

figure 5 shows a third embodiment of the device according to the present invention, seen from the side,

figure 6 shows the device in figure 4 placed in a breeding pen, and figure 7 shows the device in figure 4 placed in the bottom of a breeding pen.

In the figures and the following description, similar parts, or parts with the same or similar function, are marked with the same reference designations. Furthermore, designations such as "upper", "lower" etc. linked to how the device according to the invention is oriented in the water during use, as is generally evident from the figures.

With reference to Figures 1 to 3, a device for feeding fish according to a first embodiment of the invention is shown. A retainer 1, preferably for pellet feed, is arranged on a raft 2 which floats on the water surface. A feed screw 3 transports feed from the reservoir 1 to the inlet of a supply hose 4 which is in turn connected to a transition pipe 5. The transition pipe 5 is led sealingly through an opening in the bottom of a funnel-shaped collection device 6. An ejector riser pipe 7 with a cross-sectional area, preferably circular, which is larger than the transition pipe 5 is preferably arranged coaxially with the transition pipe 5, and where the transition pipe 5 is partially inserted into it.

Advantageously, a number of struts (not shown) between the ejector riser 7 and the bottom of the collection device 6 can attach the ejector riser 7 to the collection device 6, and where the gap between the ejector riser 7 and the bottom of the collection device 6 can preferably be adjusted with suitable adjusting means, such as for example that the ends of the rods are adjustable fixed in a groove in the ejector riser 7. It will thus be possible to achieve an adjustment of the gap between the bottom of the ejector riser 7 and the bottom of the collection insert 6, so that the ejector effect that is formed in this area reaches the main flow of water, possibly a mixture of water and for, pumped through the transition pipe 5 and further out through the ejector riser 7 will be able to be adapted to the relevant enlargement (pellet size). The dashed arrows show how the current is drawn into the ejector.

A pump 8 is connected to the supply hose 4 in order to pump water out into the supply seal hose at high speed. With reference to Figure 3, it appears that the pipe 9 from the pump 8 enters the supply hose, and is preferably arranged coaxially with this over a limited length. The lining which is supplied to the supply pipe 4 by falling into it from the feed screw 3 will thus be pulled with the water flow with the ejector effect. In this way, the lining can advantageously be supplied without passing through the pump 8, and thus avoid being crushed into smaller pieces. When using an impeller pump, the pellets do not come into contact with the vanes, and are therefore not damaged. However, large pellets for halibut will require larger pump housing dimensions compared to the current version.

Furthermore, a return sensor 12 is advantageously arranged on the ejector riser 7, and measures the amount of mold that flows through it at any time. The return sensor is connected to a control system known per se for the supply of new feed, so that when the return sensor 12 detects too little feed through the ejector riser 7, more feed will be supplied from the feed container 1, so that the supplied amount of feed is at all times determined by the fish's appetite.

With reference now to figures 4 to 6, an alternative second embodiment of the present invention is shown. This mainly differs from the above-described embodiment in that it is not based on the ejector pin sip, neither when feeding to the supply hose 4 nor when recirculating the feed from the recycling unit 6. The feed discharged from the container 1 is sucked into the pump 8 together with water, and is carried on through and out of a riser 7' which is led sealingly through an opening at the bottom of the funnel-shaped collection unit 6. The unused feed that accumulates at the bottom of the collection device 6 after first being thrown upwards from the exit of the riser 7' is pumped out through a second opening at the bottom of the collection device 6 which is sealingly connected to a recycling pipe 13 connected to a second pump 14. A recycling riser 15 is again connected to the pump 14, and passes sealingly through a third opening at the bottom of the funnel-shaped collection device 6.

As an alternative (not shown) to starting from a second opening at the bottom of the collection unit 6, the recycling pipe 13 can be arranged as a preferably 180° designed pipe bend which is led through an opening at the bottom of the collection unit 6, and where the free suction end of the recycling pipe 13 is arranged at a distance above the bottom, and directed down towards it. In this alternative, there will be no opening at the bottom of the collection unit 6, and the material that collects at the bottom of this is sucked upwards by the action of the pump 14 and into the recirculation pipe 13 for recirculation through the recirculation riser 15.

As a further (not shown) alternative, the entire recirculation device, consisting of recirculation pipe 13, pump 14 and recirculation riser 15, can be arranged within the funnel-shaped collection device 6, and where the lining collected at the bottom is sucked upwards and into the recirculation pipe 13 as for the aforementioned alternative .

A return sensor 12 is advantageously arranged on the recirculation riser 15 to measure the amount of mold that passes through it. As for the first embodiment of the invention, the return sensor 12 is advantageously connected to a control system known per se for the supply of new lining, so that when the return sensor 12 registers too little lining through the recirculation riser 15, new lining will be supplied from the reserver 1, so that the added amount of lining at all times here, too, is determined by the fish's appetite.

One also envisages a simpler variant of the invention, where allocation of new lining takes place from a feeding machine/container, or alternatively the discharge point from a central feeding facility, which is located above the collection device. This can be particularly relevant where the collection device is placed at depths down to 4 - 6 meters below the water surface. With reference now to Figure 5, a third, simpler embodiment of the invention is thus shown, where the pre-supply takes place at the surface by means of a feed silo 1' with a dosing unit, instead of via a supply hose 4 to the bottom of the collection device 6 as for the first and the other embodiment. At the bottom of the collection device 6, as in the first embodiment, shown in figures 1 and 2, a recirculation device is arranged in the form of an ejector riser 7 connected to a transition pipe 5 and a pump 8. Alternatively, a recirculation riser 15 connected to a recirculation pipe 13 and a pump 14, according to the second embodiment shown in figure 4, is used for recycling the lining. A combined supply of new lining from the surface, as for the third embodiment, and from the collection device via a supply hose 4, as for the first and second embodiment, is also conceivable.

Furthermore, with reference to Figures 1 and 4, for all the embodiments a net 10 is advantageously arranged over the upper opening of the funnel-shaped collecting device 6 to prevent fish from going down into it. The area of the upper opening in the collection unit 6 is also preferably so large that everything that is thrown up from the riser 7 is caught by the collection unit 6 when it sinks back down, also under the influence of possible underwater currents. The collection device 6 is further advantageously held up by floating bodies 11 which float on the surface of the water.

Experiments also show that recycling faeces does not pose a problem, as these dissolve and disappear due to the pump pressure during recycling.

In conclusion, figures 6 and 7 show the device according to the second embodiment of the present invention placed in a breeding cage 16 where the insertion point is lowered into the cage or placed at the bottom of the cage 16 for feeding, for example, halibut in a flat-bottomed cage 16.

With reference to the above, it must be emphasized that the features of the described embodiments can of course be combined without deviating from the invention. Thus, for example, the ejector-based recirculation unit for the first embodiment can be combined with the non-ejector-based pre-supply to the supply pipe for the second embodiment, and vice versa. A different number of components than in the above-described embodiments can also be provided, for example a different number of risers, pumps or the like, without deviating from the invention.

Claims (14)

1. Device for feeding fish, including a retainer (1), a supply hose for feed (4), a supply device for feed (7; 7'), a pump (8) for pumping the feed mixed with water through the supply hose (4) and the supply device (7; 7'), and a collection device (6) in the form of a funnel to collect unused material at the bottom of the collection device (6) for recycling thereof, characterized in that the supply device (7; 7') is arranged by the bottom of the funnel-shaped collection device (6) in order, with the action of the pump (8), to throw the lining upwards towards, and preferably out past, the upper opening of the funnel-shaped collection device (6). 2. Device according to claim 1, characterized in that the collected feed in the collection device (6) is recycled in a recycling device associated with the collection device (6), without having to be brought up to or above the water surface for recycling through the supply hose (4) together with newly added feed. 3. Device according to claims 1 to 2, characterized in that the recycling device consists of an ejector in the transition between a transition pipe (5) connected to the downstream end of the supply hose (4) and an ejector riser (7) for ejecting the lining through the upper end of the riser (7), the riser (7) being provided with a cross-sectional area at the lower end that is larger than the cross-sectional area at the opposite end of the transition pipe (5), that the transition pipe (5) is sealingly connected to the collection device (6) through an opening at the bottom of this, and that the transition pipe (5) is preferably arranged coaxially with the ejector riser (7) and partially introduced into it, so that between the transition pipe (5) and the riser (7) a gap is formed for the ejector action to pull the lining together in the bottom of the collection device (6) for recirculation through the ejector riser (7). 4. Device according to claims 1 to 2, characterized in that the recycling device (6) includes a second pump (14) connected to a recycling pipe (13) starting from and sealingly connected to an opening in the bottom of the collection device (6), and one from the pump and recirculation riser (15) connected through a second opening at the bottom of the collection device, and where new feed is supplied through a separate riser (7') which is led through a third opening at the bottom of the collection device (6). 5. Device according to any one of the preceding claims, ^. characterized in that a return sensor (12) for measuring the amount of mold is arranged on the ejector riser (7) or the recirculation riser (7'). 6. Device according to claim 5, characterized in that the return sensor (12) is connected to a control system for the delivery of new lining, so that when the return sensor (12) registers too little lining through the riser (7; 7') new will remain supplied from the reserve ( 1), so that the amount of feed added at any time is determined by the fish's appetite. 7. Device according to any one of the above claims, characterized in that a net (10) is arranged in the upper opening of the funnel-shaped collection device (6) to prevent fish from going down into it. 8. Device according to claim 3, characterized in that the height of the slit opening can be adjusted in relation to different fore types (pellet sizes). 9. Device according to any of the preceding claims, characterized in that the supply of feed between the reservoir (1) and the supply hose (4) takes place with an ejector effect, and that the feed supply point is located after the pump (8), so that the supplied feed does not passes through the pump (8). 10. Device for feeding fish, including a reserve (1') for the allocation of feed in one or more allocation points above a collection device (6) in the form of a funnel to collect unused feed at the bottom of the collection device (6) for recycling this , characterized in that the collected feed in the collection device (6) is recycled in a recycling device associated with the collection device (6) without having to be brought up to or above the water surface in a hose for recycling. 11. Device according to claim 10, characterized in that the recycling device consists of an ejector in the transition between a transition pipe (5) and an ejector riser (7) for ejecting the lining through the upper end of the riser (7), the riser (7) is provided with a cross-sectional area at the lower end that is larger than the cross-sectional area at the opposite end of the transition pipe (5), that the transition pipe (5) is sealingly connected to the collection device (6) through an opening at the bottom thereof, and that the transition pipe (5) is preferably arranged coaxially with the ejector riser (7) and partially introduced into it, so that a gap is formed between the transition pipe (5) and the riser (7) in order to draw with it the material gathered at the bottom of the collection device (6) for recycling through the ejector action the ejector riser (7). 12. Device according to claim 10, characterized in that the recycling device (6) includes a pump (14) connected to a recycling pipe (13) starting from and sealingly connected to an opening at the bottom of the collection device (6), and one from the pump and through a second opening at the bottom of the collection device connected to the recirculation riser (15). 13. Method for feeding fish from a device comprising a reservoir (1), a feed hose (4) for feed, a feed device (7; 7') for feed, a pump (8) for pumping the feed mixed with water through the feed pipe (4 ) and the supply device (7; 7'), and a collection device (6) in the form of a funnel to collect unused material at the bottom of the collection device (6) for recycling it, characterized in that the supply device (7; 7') is located at the bottom of the funnel-shaped collection device (6) ensures, with the effect of the pump (8), to throw the lining upwards towards, and preferably out past, the upper opening of the funnel-shaped collection device (6). 14. Method for feeding fish, including a reserve (1') for the allocation of feed in one or more allocation points above a collection device (6) in the form of a funnel to collect unused feed at the bottom of the collection device (6) for recycling thereof, characterized by recycling the collected lining in the collection device (6) in a recycling device connected to the collection device (6) without having to bring the lining up motels above the water surface in a hose for recycling.