NO342541B1 - Retractable lace skirt - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The invention relates to a retractable lice skirt for a farmed cage comprising at least one lice skirt which alone or collectively surrounds the upper part of the cage, at least oxygen sensor located in the cage, at least a winch with at least one rope, a chain or a wire, at least one motor connected to the at least one. winch, and least processor. Winch and motor are attached to the cage and power from motor is transferred to winch. Each rope attached to the winch has an end attached to the bottom of the lace skirt, from which the rope is guided to the winch by means of guide means. The processor activates at least one motor and at least one winch to pull up all or part of the lace skirt based on the oxygen measurement from the at least one oxygen sensor.

Description

The subject area of the invention

The invention relates to lice skirts to protect cages against harmful aquatic organisms such as salmon lice. More specifically, the invention relates to a tarpaulin or sheet, hereinafter called a louse skirt, which prevents harmful aquatic organisms from coming into contact with and infecting aquatic organisms, in particular farmed salmon, where the louse skirt can be raised upon observation of low oxygen levels in the cage to restore the oxygen level and lowered again when oxygen levels are restored.

Background for the invention

Salmon lice are a species in the group of jumping crayfish. It lives as a marine parasite on salmonids. It feeds on the mucus, skin and blood of the fish. The head chest piece is wide and shield-shaped, and is used as a suction cup. The rear body is narrower, and in the female filled with eggs. The female's rear body also has two long egg sacs or roe rods. In the free-swimming nauplius stage, it has a length of 0.54 to 0.85 mm. In the copepodite stage, it is approx. 0.7 mm long and attacks the fish. In the chalimus stage, it is 1.2 to 2.8 mm long.

Salmon louse is a naturally occurring ectoparasite that has direct transmission between hosts (salmon) by means of planktonic larval stages. They are light-sensitive and mainly stay in the top 10 meters of the water bodies, where we also produce the salmon. With the increasing salmon production, the problem with salmon lice has also exploded and is the biggest fish health problem the industry has.

The industry has struggled with salmon lice for many years and has been dependent on chemotherapeutic treatments, but frequent and continuous use of these has led to the development of reduced sensitivity and resistance to these in the salmon lice. Biological control using wrasse that eat lice has increased in recent years to keep salmon lice infections down, but the wrasse is sensitive to temperature and is thus unsuitable for use where temperatures are below 6 °C, which we have in periods in the northernmost counties.

Salmon lice graze on the skin and mucosal tissue of the fish so that wounds occur, thereby making it susceptible to secondary infections and osmotic stress. Salmon lice has had a major impact on the economy of the farming industry as it leads to reduced growth, increased waste of feed, downgrading of products and expensive treatments. It is estimated that the problem with salmon lice alone is in the order of €150 million annually.

It has been shown that salmon lice infections in farms are transferred to wild fish. Salmon lice do not like fresh water and stay under the fresh water layer that the spring flood creates in the fjords. Fish swimming in this layer are therefore protected against infection.

Attacks by parasites on aquatic organisms in breeding facilities can lead to large economic losses, great suffering in the farmed animals and a great risk of infection from the breeding facility to the surroundings outside. Among the fish that are suitable for farming are salmon and trout. To counteract or avoid attacks by parasites, it is known to lay a lice skirt on the outside and around breeding cages, both around the entire cage and its upper part, which is impervious to parasites, such as salmon lice. Salmon lice are organisms that move in the upper few meters of the water column. Experiments have therefore been carried out with different depths on the louse skirts around the cages. Depths between 3 and 15 meters have been tested and a depth of at least 6 meters on the skirts seems to give good results, however depending on the degree of turbulence in the water. The mesh size of such a lice skirt should be well under 1mm, which reflects the size of the salmon lice, dense membranes are also used, but this reduces the flow of fresh water and thus the oxygen level.

However, experience with lice skirts shows that the oxygen level in cages with lice skirts is also too low in periods, especially at night when the oxygen level is the lowest, because much of the oxygen in the water is produced by photosynthesis from plants and algae. The oxygen level in salt water varies daily and annually with a sinusoidal curve. The daily variation is due to the supply of oxygen due to photosynthesis in plants and algae, while the annual variation is mainly caused by temperature where cold water dissolves more oxygen than warm water. This means that oxygen levels are highest in the afternoon and lowest late at night due to the diurnal variation, and that oxygen levels are highest in late winter and lowest in late summer due to the annual variation. In addition, there are a large number of local variations such as weather parameters, nutrient content, density of oxygen consumers, acidity, etc.

The salmon should have at least 70% oxygen saturation in the water. There have been examples of widespread fish deaths due to lack of oxygen in cages with lice skirts. The lack of oxygen is usually not long-lasting. Therefore, it may be appropriate to pull up the lice skirt during the relatively short period when the lack of oxygen occurs without the protection against salmon lice being significantly reduced. The retractable lice skirt according to claim 1 solves this problem.

Botnegård has described on its website (http://www.fhf.no/media/67846/perma-skirt_-_knut_botng_rd_-_botngaard.pdf) that the skirts have a lifting system so that they can be lifted up quickly if the oxygen level gets too low. In an article in kyst.no (http://kyst.no/norsk_fiskeopdrett/permaskjorthindrer-paslag-av-lus-4/) it is stated that a rope is mounted vertically on the skirt throughout, so that the skirt can be lifted like a lift curtain . US 6062170 A describes that the tarpaulin can be raised by supplying air to a boom fixed at the bottom of the tarpaulin, so that water in the boom is displaced. To lower the tarpaulin, the air is displaced by supplying water to the boom. NO 334957 B1 describes a cage comprising float collar, net bag and bottom ring, where lines run from the float collar to the bottom ring, and at least one device for tightening and pulling up the lines, an upper end of the lines being attached to the device and a lower end being attached to the bottom ring.

Summary of the invention

The invention relates to a retractable lice skirt for a rearing pen which includes

at least one lice skirt which alone or collectively encircles the upper part of the cage, an energy source, at least one oxygen sensor located in the cage, at least one winch with at least one rope, one chain or one cable, at least one motor connected to the at least one winch and at least one processor .

The retractable lice skirt is characterized by further comprising a winch and the motor is attached to the cage and power from the motor is transferred to the winch, where each rope has an end that is attached to the bottom of the lice skirt, from which the rope is led towards at least one winch by means of conductors . Furthermore, the processor is adapted to activate at least one motor and at least one winch to pull up all or parts of the louse skirt and the degree of raising or lowering of the louse skirt is steplessly controlled by the oxygen level in the cage.

Brief description of the figures

Fig.1 shows a lice skirt with a winch and a rope for pulling up the lice skirt.

Fig 2 shows another design with two ropes for one winch and one motor.

Fig 3 shows a preferred design seen from above with four motors and four winches

Detailed description

In what follows, we assume that the directions are described based on a retractable lice skirt that is mounted on a cage, and that rope, chain and cable are referred to collectively as rope for the sake of simplicity.

Figure 1 shows a simple embodiment of a retractable lice skirt 1 for a breeding cage 2 comprising at least one lice skirt 1 which alone or collectively envelops the upper part of the cage 2. At least one oxygen sensor 3 is placed in the cage, to observe the oxygen level. It can be useful to have several sensors at several heights and also some on the outside of the cage to observe the difference between the cage and the surrounding water. The retractable lice skirt must also have at least one winch 4 with at least one rope 5, one chain or one cable, and at least one motor 6 which is connected to the at least one winch 4.

Furthermore, there must be at least one processor 7 which receives data from the at least one oxygen sensor 3 and an energy source 8 such as a battery, a generator, the local power grid etc. which supplies the processor, motor and sensors with energy. The dashed line in Figure 1 shows the louse skirt in a pulled up state.

Winch 4 and motor 6 must be attached to the cage and power from the motor must be transferred to the winch.

Each rope 5 which is attached to the winch has an end which is attached to the bottom of the lice skirt 1. The rope is guided from the bottom of the lice skirt towards the winch by means of guiding means 9, such as e.g. can be pulleys, leads, pipes and holes, alone or in combination. In Figure 1, the guide means 9 is a tube to guide the rope 5 over the edge of the cage 2 and to the winch 4

In one embodiment, the guiding means 9 guide the rope 5 first approximately vertically towards the surface, and then towards the winch 4 or there may be one motorized winch for each rope which is attached to the bottom of the lice skirt 1. In another embodiment, the ropes 5 are attached to one gathering rope in a distance from the winch 4, which corresponds to the pull-up length of the lice skirt 1, when the lice skirt 1 is in its lowest position.

In a preferred embodiment, there are four motorized winches 4 distributed around the cage, e.g. for every 90 degrees around the circle, each with a rope 5 attached to the bottom of the louse skirt 1.

Degree of pulling up of the louse skirt 1 can be controlled steplessly by the oxygen level in the cage 2 or at least one motor 6 and at least one winch 4 is activated to pull up all or part of the louse skirt 1 when the oxygen level is below a first predetermined level N1 and activates at least one winch 4 for to drop all or part of the louse skirt 1 when the oxygen level is above a second predetermined level N2. It is also possible to operate with several predetermined levels, each with a different degree of pull-up. PLC control will be a cost-effective and robust solution.

In one embodiment, the processor 8 activates at least one motor 6 and at least one winch 4 to pull up all or parts of the louse skirt 1 based on oxygen measurements from the at least one oxygen sensor 3 in the cage 2. In a more preferred embodiment, depth profiles of oxygen measurements are used on the inside and the outside of the cage to achieve minimal pull-up of the louse skirt without going below a minimum predetermined oxygen level in the cage.

Claims (6)

Pa ten tkra v 1. Retractable lice skirt (1) for a rearing cage (2) comprising: at least one louse skirt (1) which, alone or collectively, encircles the upper part of the cage, an energy source (8), at least one oxygen sensor (3) placed in the cage (2), at least one winch (4) with at least one rope (5), one chain or one cable, at least one motor (6) connected to the at least one winch (4), at least one processor (7), characterized by that winch (4) and motor (6) are attached to the cage and power from the motor is transferred to the winch, where each rope has an end which is attached to the bottom of the lice skirt, from which the rope is guided towards the at least one winch by means of guides (9), and where the processor (7) is adapted to activate at least one motor and at least one winch to pull up all or parts of the lice skirt and where the degree of raising or lowering of the lice skirt is continuously controlled by the oxygen level in the cage. 2. Retractable louse skirt according to claim 1, where the guide means (9) are at least one of: pulleys, guides, pipes and holes. 3. Retractable lice skirt according to claim 1, where the guide means (9) first guide the rope approximately vertically towards the surface, and then towards the winch (4). 4. Retractable lice skirt according to claim 1 where there is one motorized winch (4) for each rope (5) which is attached to the bottom of the lice skirt (1). 5. Retractable lice skirt according to claim 1 where there are four motorized winches (4) distributed around the cage, each with a rope (5) attached to the bottom of the lice skirt (1). 6. Retractable lice skirt according to claim 1, where all the ropes are attached to one rope at a distance from the winch that corresponds to the pull-up length of the lice skirt when the lice skirt is in its lowest position.