NO323506B1 - Use of protein separator for fun - Google Patents

Description

USE OF PROTEIN SEPARATORS FOR SEA WATER

Introduction

The present invention relates to a separator, also a cat skimmer or skimmer, for removing protein from water in breeding facilities and aquariums. In particular, the invention applies to a protein separator for seawater circulation in a breeding facility for food fish or an aquarium for relatively large quantities of aquarium fish, e.g. Koi fish, or other seawater fish species, or for other seawater organisms, e.g. sea crayfish.

Backround for the invention

A problem which is sought to be reduced by the present invention is the supply of air

to the water during the cleaning process. If you add air in the form of compressed air or bubbles to the water, much of the nitrogen gas in the air will dissolve in the water. This can lead to an unwanted nitrogen content in the water. It is known that nitrogen dissolved in the water inhibits fish growth, so it is desirable that the nitrogen content in the water is sufficiently low that it does not inhibit the growth of fish.

It is part of the known technique to remove particles and proteins from water by adding air and forming air bubbles in the water so that the particles and proteins are bound to the bubbles and thereby forced to the surface where they can be skimmed off. The effectiveness depends on many conditions, where density and pH are important. pH is important as fresh water usually has a lower pH than salt water. This will reduce the electrical bonds that form between particles in fresh water. Bubble formation for protein skimming has therefore traditionally been carried out within the indicated salinity range from around 10 to around 50 parts per thousand, where the bubble size will be in the range of around 0.1 mm to around 1 mm. Freshwater also has a lower density than saltwater, and this makes it more difficult to form stable small bubbles. The attached Fig. 12 shows a range for bubble size in relation to different values of the water's salt content. It has not been common to try to remove protein from water with a salinity of less than about 5-10 parts per thousand.

Kient technique

It is known to use so-called bubble stones by forcing added air out through

such a bubble stone under water. The bubbles that are then formed can have a small diameter, even if they are formed in almost fresh water, and will be able to capture a number of proteins from the water.

However, the bubbles will be unstable in fresh water and thereby merge into larger bubbles so that they quickly end up within large bubble sizes between approx. 2 mm and 5 mm as shown in the left part of the stable bubble size range shown in Fig. 12.

US 3,661,262 (Sanders) relates to a filtration and circulation system for maintaining water quality in an aquaculture tank (eng.: "Filtration and circulation system for maintaining water quality in mariculture tank"). This US patent shows a protein skimmer with the reference number "20" in the upper right corner of the drawing, and shows a similar Y-tube connection which is mounted with the main run vertical and which is not used for the discharge of water.

US 3,965,007 (Conn et al.) discloses a protein skimmer for use in a recirculating water aquarium. It uses an air bubble injector at the bottom of a tube near the bottom in the water. Injection of bubbles is a disadvantage due to the danger of elevated nitrogen content in the water, which usually leads to poorer fish growth. Bubbles in the water form more easily in fresh water and are not desirable because fry can mistake air bubbles for precursor particles.

US 3,994,811 (Cohen et al.) shows in the same way as US 2,965,007

(Packard) a skimmer and carbon filtration unit where compressed air is supplied to the water at a desired depth and where the water near the top of the unit has an overflow for the formation of foam and where the water runs further down to the charcoal filter. The supply of compressed air is undesirable as explained above.

US 4,988,436 (Cole) includes a protein skimmer (shown in US Patent Fig. 1 and

2) with air injection pump 71 and an air pipe 129 to bubble diffusers 127 and 131, which form bubbles that collect up in extraction chamber 99 where protein foam collects. The disadvantage of the invention described in this US patent is again the unwanted air injection.

US 5,628,905 (Montalbano) describes another protein skimmer with air injection

for a porous bubble diffuser, see reference number 41 in fig. 3 and 4 of the US patent.

US 5,736,034 (Phillips) shows a tangential horizontal inlet for a mixture of water and air from a pump to a vertical pipe of larger diameter than the horizontal inlet, where a vortex is formed, and where the vortex is directed up through a central tube to the surface where foam forms that can be skimmed off. The present invention is substantially different from this.

US 6 156 209 (Kim) shows a bubble chamber with air at the top. In the bubble chamber, water is flushed down towards the water's surface, where foam is formed, collects on the surface and rises in a foam riser. Water with less protein content is taken out near the bottom of the bubble chamber. This US patent also does not show a backward side branch on a water pipe.

US 6,303,028 (Marks et al.) shows protein foam formation just in the water-air contact when an air/water mixture is circulated over a barrier inside an inverted funnel. Protein foam forms and oozes up and out through the funnel's upper, narrower opening and can be drained away from an upper tank. This also does not show any straight part of the outlet pipe. Furthermore, the US patent requires air mixing and also does not show any backward-sloping side branches, in contrast to the present invention.

The above-mentioned known technique does not solve the problem that arises from excessive nitrogen content in the fresh water, which leads to reduced fish growth. In salt water, bubbles are not as large as in fresh water. The formation of bubbles in fresh water creates such large bubbles, see Fig. 12, that the fry can mistake bubbles for bait, which means that the fry can end up higher in the water than is favorable for the fry's light conditions, temperature or risk of being eaten, or that it gets too few sheep. In the present invention, which applies to a protein separator for seawater, this problem is not significant.

Norwegian patent application N020040521 shows a device that exclusively describes the use of a protein separator for the purification of fresh water contaminated by proteins secreted from freshwater fish, where the protein separator comprises a straight pipe for the flow of fresh water, and with an upwardly directed stand pipe which is directed backwards in relation to water flow direction under the side branch, and where protein foam is secreted in the intersection between the pipe and the side pipe in connection with the rapid passage of the water past the side pipe.

The invention briefly summarized

This invention relates to the use of a protein separator for use in the purification of protein-contaminated seawater when farming seawater fish or other seawater organisms, where the protein separator comprises an inlet pipe for the supply of protein-contaminated seawater as well as an outlet for purified seawater, where the protein separator comprises the following features: a pipe comprising a mainly horizontal, straight section with at least one upwardly directed side branch which has an opening to the air, where the mainly horizontal straight section is arranged for rapid passage of the water past the side branch and to have the water level close to the elbow above the connection of the side branch with the straight section, and

where the side branch is directed backwards in relation to the direction of water flow in the straight part, and forms a first angle which is less than approximately 90° with the straight part,

so that during water flow a protein foam is secreted at the water surface at the intersection of the side branch with the straight part of the pipe, and that the protein foam is allowed to rise from the water surface for discharge through the side branch, and where the pipe is further arranged so that the completely or partially purified water flows on through the straight part the lot and directly or indirectly to the expiry.

The invention also relates to a process for purifying seawater in farming

of seawater fish or other seawater organisms using a protein separator, characterized in that the process comprises the following steps: supply of purified or partially purified water to a pipe with a substantially straight section with one or more upwardly directed side branches, where each side branch has an opening leading to air;

rapid flow of the water past the side branch, while the water level is kept close to or above the connection of the side branch with the straight part, the side branch being directed backwards in relation to the direction of water flow in the straight part, and forming a first angle of less than approximately 90° with the straight part, so that a protein foam is separated at the water surface at the intersection of the side branch with the straight part of the pipe, and that the protein foam is allowed to rise from the water surface for withdrawal through the side branch; and

onward flow of the fully or partially purified water further through the straight part of the pipe and directly and indirectly to the outlet.

Further features of the use of the protein separator and the process according to the invention are described in the associated subordinate patent claims.

Theaninase overview

The invention is illustrated in the attached drawings which are only intended to illustrate the invention, and which should not be understood as limiting the scope of the invention.

Figure 1 is a schematic section in the vertical plane of a possible embodiment of a breeding facility for saltwater fish or other saltwater organisms with a pool for breeding saltwater fish or other saltwater organisms. There is an outlet pipe for water from the pool to a pump for circulation of the water, as well as a return pipe for water from the pump to the pool. Furthermore, in this embodiment, a separator is shown, here a filter tank with a particle filter which is arranged between the outlet pipe from the pool and the return pipe to the pool.

A side branch is arranged on a mainly horizontal, straight part of the return pipe. The end or outlet of the return pipe is shown here bent upwards in relation to the horizontal main course of the return pipe.

Figure 2 is a schematic vertical section similar to Figure 1, where the separator is a trap tank

or drop chamber.

Figure 3 is a very simplified schematic (partially transparent) perspective drawing showing a section of an embodiment of the return pipe with the straight part, the side branch and the outlet for the return pipe, where the cross sections of the straight part, . the side branch and the outlet for the return pipe are mainly circular. Figure 4 is a very simplified schematic (partially transparent) perspective view showing a section of the return pipe with the straight part, the side branch and the outlet for the return pipe in another embodiment where the cross sections of the straight part, the side branch and the outlet for the return pipe are square. Figure 5 is a very simplified schematic (partially transparent) perspective view similar to Figure 3, which shows a section of a further embodiment of the invention where several side branches are arranged in a row along the pipe, here shown in an embodiment of the invention with two side branches arranged in a row . Figure 6 is a very simplified schematic side view similar to Figure 4, where several side branches are arranged across the width of the tube, here shown in an embodiment of the invention where four side branches are arranged next to each other. Figure 7 shows a very simplified schematic vertical section where an embodiment of the invention is shown where the outlet of the return pipe is bent in relation to the main course of the return pipe. In this embodiment, it is possible to adjust the height by the fact that the connection between the outlet and the return pipe's main run is rotatable about the central axis through the return pipe's main run. Figure 8 shows a very simplified schematic vertical section similar to Figure 7, where an embodiment of the invention is shown where the outlet of the return pipe is connected to the return

the main run of the pipe. In this embodiment of the invention, the transition is shown articulated in the form of a flexible hose section.

Figure 9 shows a schematic sketch of a vertical section similar to Figure 7, where the pipe

the straight part is arranged lower in relation to the main course of the return pipe.

Figure 10 shows a schematic sketch of a vertical section similar to Figure 8, where the pipe

straight part is narrowed in relation to the main course of the return pipe.

Figure 11 shows an improved preferred embodiment of the invention in different views. Fig. 11a shows a partial vertical section and outline of an embodiment with an inlet pipe at the top with water sprinkled down through a particle filter, and a longitudinal section and outline of a horizontal outlet pipe with a protein separator according to a preferred embodiment of the invention. Fig. 11b likewise illustrates a partial vertical section and view of the same embodiment of the invention, seen in partial section and view right into the longitudinal axis of the outlet pipe, i.e. 90° in relation to Fig. 11a. The stream of water is intended to run out towards the reader. Fig. 11c shows a horizontal section through the protein separator according to the invention seen directly from above. Figure 12 shows a Cartesian diagram of air bubble diameter in relation to salt concentration in water.

A more detailed description of the protein separator according to the invention will be given below, with reference to the attached drawings.

r

Description of preferred designs

Reference is now made to fig. 1, where a simple breeding facility is shown with a pool 2 for breeding saltwater fish or other saltwater organisms with a protein separator according to a possible embodiment of the invention. There is an outlet pipe 4 for water from the pool 2 to a pump 5 for circulation of the water, as well as a return pipe 3 for water from the pump 5 to the pool 2. Furthermore, in this embodiment, a filter tank 1 is shown with a particle filter 7 which is arranged between the outlet pipe 4 from the basin 2 and the return pipe 3 to the basin 2. A side branch 9 is arranged on a mainly horizontal, straight part 90 in the return pipe 3. The end or outlet 31 of the return pipe 3 is shown here bent upwards in relation to the horizontal main course of the return pipe 3 .

The protein separator according to the invention is designed for use when purifying saltwater when breeding saltwater fish or other saltwater organisms in a pool 2. The breeding facility is provided with a circulation system comprising one or more outlet pipes 4 for water from the pool 2, where the outlet pipe 4 leads on to a pump 5 for circulation of the water, as well as a return pipe 3 to lead water directly or indirectly from the pump 5 to the pool 2, in a preferred embodiment via a filter 15, 7 as explained below.

The return pipe 3 comprises a mainly horizontal, straight section 90 with at least one upwardly directed side branch 9 which has an opening 91 which leads to air. The mainly horizontal straight part 90 is advantageously arranged for rapid passage of the water past the side branch 9 and further to have the water level close to or above the connection of the side branch 9 with the straight part 90. The side branch 9 points backwards in relation to the direction of water flow in the straight part 90, and forms a first angle v of between 0° and approximately 90° with the straight part 90, as shown in fig. 1 and fig. 7. The first angle v can advantageously be between approximately 30° and 60°. It is also possible that the first angle v may be between approximately 40° and 50°. In a preferred embodiment, however, the first angle v is approximately 45°.

In an embodiment of the invention, the side branch 9 can have a mainly circular or elliptical cross-section, but it can also advantageously have a mainly square cross-section, e.g. either square or rectangular. Correspondingly, the straight part 90 can also have a mainly circular or elliptical cross-section, but the cross-section can also be with fjord part be mainly square, either square or rectangular, because this will increase the intersection area between the main course and the side branch 9, in which intersection area it is believed that the protein secretion process finds place. Two possible designs of the straight part are illustrated in fig. 3 and 4. Another alternative is to let the cross section 9 of the side branch and the cross section 90 of the straight section be different, e.g. a combination of circular or elliptical cross-section for the straight part 90 and square cross-section for the side branch 9, but also a reverse combination is possible, i.e. where the straight part 90 can have a square cross-section and the side branch can have a circular or elliptical cross-section.

During water flow, a protein foam will form at the water surface at the intersection of the side branch 9 with the straight part 90 of the return pipe 3. The protein foam is allowed to grow upwards from the water surface for discharge through the side branch 9. The return pipe 3 is further arranged to allow the fully or partially purified water to flow on through the straight section 90 and run back directly or indirectly to pool 2.

The protein skimmer according to the invention for the pool 2 does not necessarily have to be exclusively for marine breeding purposes, i.e. for the commercial breeding of seawater fish or the production of seawater organisms in the pool 2. The protein skimmer for use with the pool 2 can also include protein skimmers according to the invention for use with professional aquarium tanks for displaying organisms to the public or such protein skimmers for amateur use in a small aquarium, where a return pipe 3 with side branch 9 according to the invention is used in the circuit to separate proteins from the water.

Reference is now made to fig. 9. From the figure it appears that the right part 90 also

can be arranged at a lower level in relation to the return pipe's 3 main runs. An advantage thereby achieved is a higher pressure in the straight part 90, so that separation and removal of protein from the flowing water takes place more efficiently or faster.

A further possible embodiment is that the straight part 90 can be narrowed in relation to the main course of the return pipe 3, as can be seen from fig. 10. The water flow will then have a greater speed through the narrowed straight section 90, but there will also be a pressure drop across the narrowing. It is likely that the protein secretion will be able to become more efficient.

In a further embodiment of the invention, several side branches 9 are arranged either in a row along the outlet pipe 4, as shown in fig. 5 or in width, as shown on

fig. 6. It is also possible to have several side branches 9 arranged both in a row and in width, e.g. in a 2x2 arrangement, 3x3 arrangement, 10x10 arrangement, 2x4 arrangement, or the like.

In a further embodiment of the invention, the return pipe 3 comprises an end or an outlet 31 which is bent in relation to the horizontal main course of the return pipe 3, where the outlet 31 is arranged to form a desired second angle w with the main course. The second angle w can be between 0° and approximately 90°, but also between approximately 30 and 60. The second angle w between the central axis through the return pipe 3 and the central axis through the outlet 31 is advantageously approximately 45°.

The protein separator in its very simplest and original design was found by chance because an outlet pipe 3 from a freshwater protein separator was too short, and a Y-pipe connection was inserted with one straight main run 90 with an approx. 45° side run 9, where the straight main run 90 was only spliced into the outlet pipe 3, and where the side run 9 was directed upwards and backwards in relation to the water flow so as not to disturb the water flow unnecessarily. It turned out that protein foam came out of the side channel 9. The inventor assumed that the invention would only work for fresh water, which later attempts prove to be wrong, because he has now tried to use the device for fish in a seawater pool, and it is separated protein foam also from the salt water.

The outlet 31 can in one embodiment be a fixed pipe part where the outlet 31 with its overflow 32 forms a second angle w with the main course of the return pipe 3. The transition between the main run of the return pipe 3 and the outlet 31 can also be rotatable, so that the outlet 31 with its overflow is height adjustable, as shown in fig. 7. In another embodiment, the outlet 31 can be movable in relation to the rest of the return pipe 3, so that the outlet 31 with its overflow 32 can thus be set to the desired angle w and height in relation to the horizontal main course of the return pipe. This can be solved by the pipe being jointed, e.g. using a ball joint. Alternatively, all or parts of the pipe can be flexible. All or parts of the return pipe 3 can e.g. is made up of a snake. The transition between the return pipe's 3 outlet 31 and the return pipe's 3 main run can be formed by a hose, e.g. as shown in fig. 8. The outlet 31 can then be easily adjusted in relation to the water flow and the amount of protein that is secreted, and this leads to simpler control of the water purification process.

Overflow 32 for the cleaned water from the outlet 31 can advantageously be arranged to lie at the same level as the water level at the intersection of the side branch 9 with the straight part 90 of the return pipe 3.

In order to remove unwanted material, such as particles, gases, mucus and biological material from the circulating water, one or more separators 1,7 may be arranged; 15 which can be placed between the outlet pipe 4 from the pool and the return pipe 3 to the pool 2, preferably arranged between a feed pipe 6 from the pump 5 and the return pipe, e.g. a filter tank 1 with a particle filter 7, 3. The filter tank 1 can comprise an outlet 8

for air and gas from the particle filter 7.

The separator can also be a trap tank or a drop chamber 15, which can be arranged between the outlet pipe 4 from the pool 2 and the return pipe 3 to the pool 2, preferably arranged between the feed pipe 6 from the pump 5 and the return pipe 3. This drop chamber 15 can also advantageously have an outlet 8 for air and gas, but it can also be open to air.

At the bottom of the separator 1,7;15, there should be a certain water level, so that when water is withdrawn from the separator via the return pipe, air does not reach the return pipe 3 before separation of protein at the intersection between the straight part 90 of the return pipe 3 and the side branch 9.

During practical comparative tests, it has been observed that an adequate cleaning process does not take place when the water flows through a filter with a conventional outlet pipe and into the pool 2, without a side branch 9 being arranged in connection with the return pipe 3. This indicates that there is not is separated with sufficient protein using conventional filter tanks. By using a protein separator according to the invention, a protein separation process was achieved in the intersection of the side branch 9 with the straight part 90 of the return pipe 3. The foam formation that grew in the side branch 9 could thus be easily removed.

The water does not have to flow down into the pool 2 from the return pipe 3, but can also run straight out into the pool 2 with the lower edge or overflow 32 of the return pipe 3 in the water crust, or that the return pipe 3 opens flush with the water crust or something below the water crust in the pool 2

The invention also includes a process for purifying sea or salt water when farming salt water fish or other salt water organisms in a pool 2, using a protein separator. The process includes the following steps: supply of purified or partially purified water to a return pipe 3 leading to the basin 2, where the return pipe 3 comprises a mainly horizontal, straight section 90 with one or more upwardly directed side branches 9, each with an opening 91 leading to air , rapid flow of the water past the side branch 9, at the same time that the water level is kept close to or above the connection of the side branch 9 with the straight part 90, the side branch 9 being directed backwards in relation to the direction of water flow in the straight part 90, and forming a first angle v with between 0° and approximately 90<*> with the straight part 90, so that a protein foam is formed at the water surface at the intersection of the side branch 9 with the straight part 90 of the return pipe 3, and that the protein foam is allowed to grow upwards from the water surface for withdrawal through the side branch 9 ; and

further flow of the fully or partially purified water further through the straight part 90 of the return pipe 3 and back directly or indirectly to the pool 2.

The process can also include the step of supplying purified water to one or more separators 1,7;15 with outlet 8 for air and gas, for removing particles, gases, slime or other biological material from the water. In this way, most waste materials are removed from the water. Waste substances, such as proteins or algae, which are not removed or filtered out in the separator 1,7; 15 can then be separated out in the protein separator, before the purified water is led to pool 2.

Figure 11 shows an improved preferred embodiment of the invention in different views. Fig. 11a shows a partial vertical section and drawing of an embodiment with an inlet pipe 6 at the top with water sprinkled through a number of small holes from the inlet pipe 6 down through a particle filter 7, and a longitudinal section and drawing of a mainly horizontal outlet pipe 3 with a protein separator 9 , 90 according to a preferred embodiment of the invention. The main part of the tank 15 itself can be made up of a cylindrical piece of pipe of the desired diameter and height. In the prototype sketched in Fig. 11, the pipe has a diameter of 500 mm and a height of approx. 1500 mm. Other designs can have a much smaller diameter and length, e.g. 0=50 mm, h=100 mm for small aquarium models, and for example 0=2000 mm, h=5000 mm for large aquaculture designs. Fig. 11b likewise illustrates a partial vertical section and view of the same embodiment of the invention, seen in partial section and view right into the longitudinal axis of the outlet pipe, i.e. 90° to the section in Fig. 11a. In this preferred embodiment, the straight portion 90 of the tube or closed channel 3 has a rectangular cross-section. Likewise, the intersection between the rectangular pipe 3 and the upwardly directed side branch 9 is a plane, where the rear wall of the side branch 9 in the direction of the water's outlet rather approx. 45° backwards in relation to the top plate 95 in the rectangular tube 3. The angle of inclination for the opposite front wall of the side branch 9 is less significant than for the rear wall. In the case shown, the direction of the front wall is 90° upwards in relation to the straight part 90, as shown in Fig. 11 a. Fig. 11 c shows a horizontal section through the protein separator according to the invention seen directly from above. In this preferred embodiment of the invention, a cover 94 is also arranged on the upwardly directed side branch 9, as well as a laterally directed outlet portion 51 through which the protein foam can be fed out. The outlet portion 51 can have a sloping bottom as shown in Fig. 11B, so that the protein foam slides down and out due to its own weight. A container can be arranged under the opening of the outlet portion 51 to store the protein foam temporarily. The cover 94 will be useful when using the protein separator outdoors, where there is a risk that raindrops would otherwise wash the protein foam back down towards the water surface in the side branch 9. To help with the discharge of the foam from the side branch 9, a fan 52 can be arranged in one side wall in the side branch 9 where the fan is oppositely positioned in relation to the lateral outlet part 51, 91 where the fan 52 is arranged to blow horizontally against the foam so that it drifts towards the outlet part 51. The fan 52 can be driven by an integrated electric motor. The fan 52 can also contribute to the protein foam drying and reducing in size at the same time that it is driven away from the side branch 9 and is not allowed to flow back to the water surface below the side branch 9. The exhausted protein foam can then be stored and kept separate from the water that runs back to the foot basin 2 .

The water should be relatively free of turbulence before it passes the side branch 9 and

the straight part 90. The water flow can be adjusted with a valve (36, shown in Fig. 2) which will slightly disturb the water flow in the straight part 90.

The tank 15 should be equipped with height-adjustable support legs as shown in Fig. 11, so that the entire apparatus can be set plumb and preferably with the straight part 90 of the outlet pipe 3 level. The particle filter 7 may comprise sand, or preferably pieces of plastic which take out gas bubbles and perhaps form bubbles which are driven downwards by the water flow down through the column and out through the protein skimmer.

When testing the protein skimmer in seawater added with chicken excrement, it turns out that protein foam is separated.

Claims (28)

1. Application of a protein separator for use in the purification of protein-contaminated seawater when farming seawater fish or other seawater organisms, where the protein separator comprises an inlet pipe (4) for the supply of protein-contaminated seawater as well as an outlet for purified seawater, where the protein separator comprises the following features: a pipe ( 3) comprising a mainly horizontal, straight part (90) with at least one upwardly directed side branch (9) which has an opening (91) towards air, where the mainly horizontal straight part (90) is arranged for rapid passage of the water past the side branch (9 ) and to have the water level close to or above the connection of the side branch (9) with the straight part (90), and where the side branch (9) is directed backwards in relation to the direction of water flow in the straight part (90), and forms a first angle (v) which is less than 90° with the straight part (90), so that during water flow a protein foam is secreted at the water surface at the intersection of the side branch (9) with the pipe (3) straight part (90), and that the protein foam is allowed to rise from the water surface for discharge through the side branch (9), and where the pipe (3) is further arranged so that the completely or partially purified water flows on through the straight part (90 ) and directly or indirectly to the outlet. 2. The application according to claim 1, where the inlet pipe (4) leads from a seawater pool, aquarium or tank (2) with a circulation system comprising a pump (5) between the inlet pipe (4) and the pipe (3). 3. The application according to claim 1, where the inlet pipe (4) leads from the sea, and where the pump (5) is arranged between the inlet pipe (4) and the pipe (3). 4. The use according to claim 1, where the first angle (v) is between about 30° and about 60 5. The application according to claim 4, where the first angle (v) is between about 40° and about 50°. 6. The application according to claim 2, where the first angle (v) is approximately 45°. 7. The application according to claim 1, where one or more separators (1, 7; 15) are arranged between the inlet pipe (4) and the pipe (3). 8. The application according to claim 1, where one or more separators (1, 7; 15) are arranged between the inlet pipe (4) and the pipe (3) of the pool (2), preferably arranged between a feed pipe (6) from the pump (5 ), and the tube (3). 9. The application according to claim 7 or 8, where the separator is a filter tank (1) with a particle filter (7). 10. The application according to claim 7 or 8, where the separator is a drop chamber (15). 11. The application according to claim 7, 8, 9 or 10, where the separator (1, 7; 15) has an outlet (8) for air and gas. 12. The application according to claim 1, where the straight part (90) in the tube (3) has a circular or elliptical cross-section. 13. The application according to claim 1, where the side branch (9) has a circular or elliptical cross-section. 14. The application according to claim 1, where the straight part (90) in the pipe (3) has a square cross-section. 15. The application according to claim 1, where the side branch (9) has a square cross-section. 16. The application according to claim 1, where the straight part (90) of the pipe (3) is arranged at a lower level in relation to the main course of the pipe (3). 17. The application according to claim 1, where the straight part (90} of the pipe (3) is narrowed in relation to the main course of the pipe (3). 18. The application according to claim 1, where the pipe (3) comprises an outlet (31) which is bent in relation to the main horizontal course of the pipe (3), where the outlet is arranged to form a desired, second angle (w) with the pipe's (3 ) main run, so that the outlet (31) with its overflow (32) is height adjustable. 19. The application according to claim 1, where the outlet (31) of the pipe (3) is movable in relation to the main course of the pipe (3), so that the outlet (31) with its overflow (32) can be adjusted to a desired second angle (w) in relation to the pipe (3) main course. 20. The application according to claim 18 or 19, where the pipe (3) is completely or partially flexible, and that part or parts of the pipe (3) are made up of a hose. 21. The application according to claim 18 or 19, where the overflow (32) for the completely or partially purified water from the outlet (31) is arranged to lie at the same level as the water level at the intersection of the side branch (9) with the straight part of the pipe (3) ( 90). 22. The application according to claims 18 or 19, where the second angle (w) between the central axis through the straight part (90) of the pipe (3) and the central axis through the outlet (31) is between 0° and approximately 90°, more preferably between approximately 30° and about 60<*>. preferably around 45 23. The application according to claim 1, where several side branches (9) are arranged either in a row along the pipe (3) or across the width, or both in a row and across the width of the pipe (3). 24. The application according to claim 1, with a cover (94) over the outlet (91) of the side branch (9), to protect the secreted protein foam in the side branch (9) from being washed back down towards the water surface in the side branch (9). 25. The application according to claim 1, with a fan (52) in one side wall of the side branch (9) opposite a lateral outlet part (51, 91) where the fan (52) is arranged to blow out the foam through the lateral outlet part (51) , and to dry the protein foam. 26. The application according to claim 1, with a valve (36) arranged in the pipe (3) in or after the straight part (90) and arranged after the side branch (9) calculated in the water's ordinary flow direction. 27. A process for purifying seawater when farming seawater fish or other seawater organisms using a protein separator, characterized in that the process includes the following steps: supply of polluted or partially purified water to a pipe (3) with a mainly straight part (90) with one or more upwardly directed side branches (9), where each side branch has an opening (91) that leads to air; rapid flow of the water past the side branch (9), at the same time that the water level is kept close to or above the connection of the side branch (9) with the straight part (90), the side branch (9) being directed backwards in relation to the direction of water flow in the straight part (90), and forms a first angle (v) of less than approximately 90° with the straight part (90), so that a protein foam is secreted at the water surface at the intersection of the side branch (9) with the straight part (90) of the tube (3) , and that the protein foam is allowed to rise from the water surface for withdrawal through the side branch (9); and further flow of the fully or partially purified water further through the straight part (90) of the pipe (3) and directly or indirectly to the outlet. 28. The process according to claim 27, further comprising the following steps: supply of contaminated water to one or more separators (1, 7, 15) arranged before the pipe (3), where the separator (1, 7, 15) is equipped with an outlet ( 8) for air and gas, for the removal of particles, gases or biological material from the water.