阅读说明：本技术 用于鱼类养殖系统的生物过滤器装置 (Biofilter device for fish farming system ) 是由 尼尔斯-埃克·佩尔森 于 2019-09-04 设计创作，主要内容包括：本发明提供了一种旨在用于鱼类养殖系统的生物过滤器装置(1),所述生物过滤器装置(1)包括具有过滤介质(3)和内部构造的容器(2),所述内部构造包括具有开口输入端(6)和开口输出端(7)的至少一个竖直管(5),其中生物过滤器装置(1)连接到泵(8),该泵使得能够将液体和过滤介质(3)从容器(2)的底部(9)通过所述至少一个竖直管(5)抵靠容器(2)的顶部(10)泵送,其中上板(15)被布置成从至少一个竖直管(5)的开口输出端(7)并围绕该开口输出端向下倾斜并且在距容器的壁(13)一定距离处结束,其中上板(15)是穿孔的,并且其中再生水流出部(16)被布置在上板(15)下方。(The invention provides a biofilter unit (1) intended for use in a fish farming system, said biofilter unit (1) comprising a vessel (2) with a filter medium (3) and an internal construction comprising at least one vertical tube (5) with an open input end (6) and an open output end (7), wherein the biofilter unit (1) is connected to a pump (8) enabling pumping of liquid and filter medium (3) from the bottom (9) of the vessel (2) through said at least one vertical tube (5) against the top (10) of the vessel (2), wherein an upper plate (15) is arranged sloping downwards from and around the open output end (7) of the at least one vertical tube (5) and ending at a distance from the wall (13) of the vessel, wherein the upper plate (15) is perforated, and wherein the regeneration water outflow portion (16) is arranged below the upper plate (15).)

1. A biofilter unit (1) intended for use in a fish farming system, the biofilter unit (1) comprising a vessel (2) with a filtering medium (3) and an internal construction comprising at least one vertical tube (5) with an open input end (6) and an open output end (7), wherein the biofilter unit (1) is connected to a pump (8) enabling pumping of liquid and filtering medium (3) from the bottom (9) of the vessel (2) through the at least one vertical tube (5) against the top (10) of the vessel (2), wherein an upper plate (15) is arranged sloping downwards from and around the open output end (7) of the at least one vertical tube (5) and ending at a distance from the wall (13) of the vessel, wherein the upper plate (15) is perforated, and wherein a regeneration water outflow portion (16) is arranged below the upper plate (15).

2. A biofilter unit (1) according to claim 1, wherein said internal construction comprises a number of vertical tubes (5).

3. A biofilter unit (1) according to claim 1 or 2, wherein said at least one vertical tube (5) is arranged at or near a vertical centre line (11) of said container (2).

4. A biofilter unit (1) according to any of claims 1-3, wherein a plate (12) is arranged sloping from a wall (13) of the container (2) towards a vertical centre line (11) of the container (2), sloping downwards towards the bottom (9) of the container (2), and wherein said plate (12) extends around the entire circumference of the container (2).

5. A biofilter unit (1) according to claim 4, wherein said plate (12) is perforated.

6. A biofilter unit (1) according to claim 5, wherein a water outflow (14) is arranged below said plate (12).

7. A biofilter system comprising several biofilter units (1) according to any one of claims 1 to 6, wherein each biofilter unit (1) is connectable to other biofilter units in a module frame (17).

8. A fish farming system comprising a fish farming tank and a general recirculation loop, which firstly comprises a pre-filter, which is able to filter out contaminants intended to be sent into the wastewater, and further comprises a recirculation of water, and wherein the recirculation loop comprises a subsequent biofilter unit (1) according to any of claims 1 to 6 or a biofilter system according to claim 7, the biofilter system having one or more regenerative filter units with a regenerative recirculation loop.

9. The fish farming system of claim 8, wherein the fish farming system further comprises means for aerating and separating carbon dioxide before the general recirculation loop is completed and purified water and aerated water are returned to the fish farming tank.

10. A method for operating a biofilter unit (1) according to any of claims 1-6, wherein said method comprises pumping liquid and filter medium (3) sequentially up through said at least one vertical tube (5) from the bottom (9) of said vessel (2) against the top (10) of said vessel (2) over a time frame.

Technical Field

The present invention relates to a biofilter unit intended for use in fish farming systems.

Background

Today, different filters are used in fish farming systems. Examples are different types of cartridge filters and disc filters and biofilters such as Moving Bed Biofilm Reactors (MBBR) and Fixed Bed Biofilm Reactors (FBBR). Combinations of different filter types are commonly used in Recirculating Aquaculture Systems (RAS), where the particle removal filter is combined with a biofilter MBBR or/and FBBR. FBBR is most important to reduce particulates in the system. It is necessary to have a time-controlled cleaning and fluidizing sequence to avoid uncontrolled and undesired bacterial growth. The problem is how to ensure that the FBBR is cleaned evenly.

It is an object of the present invention to provide an improved filter for use in a water recirculation system intended for a fish farming system, wherein the improved filter provides several advantages compared to existing solutions. These advantages relate to the possibility of, for example, providing an improved regeneration cycle for the water flow, increasing the overall yield and thus the degree of water reuse and increasing the efficiency when connecting and disconnecting the filter device during, for example, a washing cycle or the like.

Disclosure of Invention

The above object is achieved by a biofilter unit intended for a fish farming system, comprising a vessel with a filter medium and an internal construction comprising at least one vertical tube with an open input end and an open output end, wherein the biofilter unit is connected to a pump enabling pumping of liquid and filter medium from the bottom of the vessel through said at least one vertical tube against the top of the vessel, wherein an upper plate is arranged sloping downwards from and around the open output end of the at least one vertical tube and ending at a distance from the wall of the vessel, wherein the upper plate is perforated, and wherein a regeneration water outflow is arranged below the upper plate.

The biofilter unit according to the invention combines the advantages of MBBR and FBBR in the same unit. In addition, the biofilter can create a controlled and safe environment in a minimum space, be built into a modular system in the factory, and be easily adjusted to the proper capacity and assembled and disassembled. This is discussed further below.

The biofilter unit according to the present invention is intended to enable internal circulation of the filtering medium inside the container. This concept according to the invention provides a better cleaning cycle in the whole system, and thus a regeneration and reuse of the water, as the cleaning process is physically more efficient, and also provides the possibility of a more efficient regeneration and cleaning cycle for filters intended for fish farming systems.

The biofilter according to the invention can be regarded as a mixture of fixed bed filters and moving bed filters. When performing a cleaning cycle, i.e. when the pump flushes the filter medium upwards through the vertical pipe, the biofilter according to the invention performs as a moving bed filter device, so that the filter medium is subsequently cleaned from contaminants on the surface by physical movement or turbulence. During this cycle, the filter media is flushed upward through the vertical tubes and then out through the vertical tubes. As discussed further below, contaminants or residues (such as, for example, particulates) and water having a relatively high concentration of contaminants may then be separated by filtration through one or more upper plates (screens or grids), wherein the contaminated fraction may then be directed to a regenerative filter device or returned to a pre-filter to enable separation and possibly also recirculation over the biological filter device. This rinsing or cleaning cycle and its time period will be discussed further below.

Furthermore, the filter medium leaving the vertical tube subsequently settles through the vessel as it is pumped up through the vertical tube, and a purified water fraction is separated in the lower part of the vessel. This purified water fraction may then be directed back to the fish farming tank.

The standard arrangement used today comprises a moving bed filter capable of removing particles and a fixed bed filter capable of subsequently purifying water. As can be understood from the above description, this is achieved in the same biofilter unit according to the invention.

Furthermore, it should be noted that the "filter medium" according to the invention may also be referred to as a filter substrate, a filter element or a biological (filter) element, for example.

In order to provide further prior art, it may be mentioned that a filter tank comprising a sand filter type is disclosed in US 5,681,472. The filter tank includes a filter bed. The treated filtrate was collected in the area of the filter above the filter bed. This is an important difference when compared to the present invention. In US 5,681,472, a design is made to provide purified water that is separated at the top. This is the opposite of the present invention. According to the invention, water intended to be separated for further regeneration (i.e. insufficiently clean water) is separated in the upper part of the vessel. However, the purified water flows out of the container at the lower part of the container. As mentioned above, the biological filter according to the invention comprises a perforated upper plate which is arranged to slope downwards from and around the open outlet end of the at least one vertical tube and which ends at a distance from the wall of the container. Further, the regeneration water outflow portion is disposed below the upper plate. These features are not provided in the sand filter according to US 5,681,472. Furthermore, it can also be said that the sand filter of the type disclosed in US 5,681,472 is not intended for large water flows, which is the case for the biological filter according to the invention. The biofilter according to the invention is intended for use in fish farming systems where such large water flows are the case.

The invention is discussed in more detail below, and various embodiments are provided and explained.

Drawings

In fig. 1, an embodiment of a biofilter unit 1 according to the present invention is shown. The biofilter unit 1 comprises a container 2 filled with a filter medium/filter element 3. In this case, these filter elements 3 are flushed out of the vertical tubes 5, which means that the container 2 is now operating in a flushing/cleaning cycle. The filter element 3 is pumped up through the vertical tube 5 from the open input end 6 and towards the top 10 of the vessel 2 and out from the open output end 7, from where the filter element 3 settles towards the bottom 9 of the vessel 2. The driving force is provided by a pump 8, which may be arranged at different locations, but in this case is positioned at the bottom 9 of the container 2. In another case, a conduit may be provided from the bottom to the pump 8 positioned below the container 2 but at the side.

Furthermore, in this case, there are two feed lines 50 supplying the container 2 with water intended to be treated in the biofilter unit 1. It should be noted that of course only one feed line 50 may be used. The water flowing into the container 2 comes from a regenerative filter or a pre-filter from which particles have been removed.

Furthermore, the perforated plate 12 is arranged to slope from the wall 13 of the vessel 2 towards the vertical centre line 11 of the vessel 2 and downwards towards the bottom 9 of the vessel 2. Furthermore, the plate 12 is arranged in the entire cross section around the vertical centre line 11, when viewed from the top 10 or the bottom 9 of the container 2. This means that all filter elements are arranged to remain inside the container 2 without passing through the plate 12. The purified water flowing through the perforated plate 12 flows out through a water outflow 14 arranged below the plate 12, in this case two such water outflows 14. Then, the purified water fraction is sent from the water outflow portion 14 to the fish farming tank.

Furthermore, the upper plate 15 is arranged to slope downwards from and around the open output end 7 of the vertical tube 5 and to end at a distance from the wall 13 of the container. The filter element 3 passes or slides on the upper plate 15 and then settles in the container 2. However, the upper plate 15 is perforated so that the contaminant and contaminated water flowing out of the open output end 7 of the vertical pipe 5 can enter through the upper plate 15 to flow out of the regeneration water outflow portion 16. This contaminated water fraction can then be sent back to a pre-filter before the biological filter 1 or, for example, to a regeneration filter, where a water recirculation back to the biological filter 1 can be performed. The recirculation flow from the pre-filter, such as a disc filter or a cartridge filter, may flow into, for example, two tubes at the top of the vessel 2, one tube on each side of the vessel 2.

In fig. 2, a biofilter installation module frame 17 is shown according to one embodiment of the present invention. Here, several biofilters 1 connected together in a module frame 17 are shown from the top.

Detailed Description

First, it should be noted that the pumps to be used in connection with the biofilter unit according to the invention may be of different types and may be located at different locations. An alternative form of placement is shown in fig. 1. According to one embodiment of the invention, a gas lift pump or gas lift pump is connected to the biofilter unit according to the invention. Regardless of the type, the principle according to the invention is to provide sufficient power input to be able to lift or pump the filter element up through the vertical tube. The pumping medium to be used may be, for example, air, such as in an air-lift pump.

The internal construction of the present biofilter unit may be of different types, geometries and sizes. The general principle of the present invention is to provide a uniform internal configuration, which may mean that a cross-section of the biofilter unit viewed from the side and/or from the bottom and/or from the top provides a uniform internal configuration. This will enable a uniform cleaning cycle when the filter media or filter elements settle down through a container outside the vertical tube after being pumped up through and out of the vertical tube.

Furthermore, operations are also typically performed in a round robin fashion. As an example, during a cleaning cycle, the retention time of one filter element from one vertical point to about the same vertical point in the vessel is about 3 to 5 minutes, i.e. pumped up through a vertical pipe from a given starting point and then settled down again to about the same starting point. After this circulation, the entire biofilter was run with the pump in the off mode to be in the fixed bed mode. This period of time may be maintained for 30 minutes to several hours, for example about 2 hours. Then, the cleaning cycle in the moving bed mode is performed again.

It should be noted that the filter element may be of any suitable type, size and material in accordance with the present invention. Also, the vertical tubes may be of different sizes and comprise different materials. Furthermore, according to a particular embodiment of the invention, the inner construction comprises several vertical tubes. Furthermore, according to another particular embodiment of the invention, the at least one vertical tube or the plurality of vertical tubes is/are arranged at or near a vertical centre line of the container. This is shown as an example in fig. 1, and this arrangement also corresponds to the uniform arrangement according to the invention.

The biofilter unit according to the invention is also capable of leading filtered purified water back to the fish farming tank. This may be done in different ways according to the invention, but according to one embodiment the mechanical filter is arranged in the lower part of the container of the biological filter device. This mechanical filter may be arranged as a perforated disc surrounding the vertical tube in the lower part of the container. This disc can also be considered as a plate. Thus, according to a particular embodiment of the invention, the panels are arranged to slope from the wall of the container towards the vertical centre line of the container, downwards towards the bottom of the container, and in the entire cross-section of the container around the vertical centre line, i.e. wherein the panels extend around the entire circumference of the container. This plate, arranged in the lower part of the container, usually has a circular cross section, so as to constitute the entire cross section of the container at the lower position of the container. Furthermore, this lower plate suitably slopes downwards from the wall and towards the vertical pipe. This shape can be seen as an inverted cone when the container is viewed in cross-section and from the side.

Furthermore, according to a particular embodiment of the invention, the sheet is perforated, such as to form a mesh or grid. In this manner, purified water can permeate through the porous disc while the filter element remains on top of the disc. Furthermore, according to another embodiment, a water outflow s is arranged below the plate. The purified water that has been treated in the biofilter unit according to the present invention may be introduced into a fish farming tank. This then forms part of the regeneration process of the fish farming system.

It should be noted that any shape of the lower plate is possible, however the above alternative has the advantage of providing uniform settling of the filter element which is then led back to the inlet of the vertical tube before being pumped up through the vertical tube in another cleaning cycle.

As suggested above, according to one particular embodiment of the invention, one or more upper plates may also be arranged near the outlet of the vertical tubes. Thus, according to a particular embodiment of the invention, the upper plate is arranged to slope downwards from and around the open outlet end of the at least one vertical tube and to end at a distance from the wall of the container. Such an upper plate can also be seen as a disc arranged around the vertical tube at its outlet, however it is inclined downwards from the centre and outwards against the wall, however, of course only a certain distance is provided so that the part outside the upper plate is free to settle for the filter element to be pumped out of the vertical tube. Furthermore, such upper plates or discs usually have a circular cross-section and are therefore shaped like a cone, which slopes downwards and has a top portion surrounding a vertical tube.

Furthermore, this plate is intended to act as a receiving surface and a filtering member for contaminated filter elements and contaminated water flowing out of the vertical pipe. Furthermore, suitably, this upper plate is also perforated, such as a mesh or grid. The contaminated water and particles that have been removed from the surface of the filter element then permeate through the perforations and may flow to a regeneration process. As will be appreciated, according to one particular embodiment of the invention, the regeneration water outflow is arranged below the upper plate. The filter element does not flow through this upper mechanical filter plate and therefore settles inside the vessel.

The contaminated water stream and particles may flow to a separate cartridge filter or disc filter or back to a pre-filter, which may also be a cartridge filter or disc filter, so that this stream can also be regenerated. Such a pre-filter may also constitute a first step in which contaminated water and fish manure from the fish tank are separated. The water fraction and particles separated therein may then be passed to a biofilter unit according to the present invention to enable further purification, separation and eventual regeneration of the water stream.

Conversely, if the contaminated water stream with particles separated in a biofilter unit according to the present invention flows to a separate cartridge filter or disc filter, such a unit may separate the water stream from the particles and the water fraction may be sent back or recycled back to the biofilter unit. However, the particles are removed. It will be appreciated that there are a number of different arrangements that can be used to incorporate the biofilter unit according to the invention into a fish farming system.

Also, the step of separating contaminated water and particles in the biofilter unit may also form part of the regeneration process of the fish farming system according to the invention.

The invention also relates to a biofilter system comprising a number of biofilter units according to the invention, wherein each biofilter unit can be connected with other biofilter units in a module frame. An example of which is shown in figure 2. The modules of the biofilter unit according to the present invention may provide an arrangement in which the biofilter units may be connected to each other as a unified unit one by one in the module frame. They may have a common outflow so that the purified water stream is returned to the fish farming tank. This may be effective for a common output stream of contaminated water and particles. The inflow of contaminated water to the biofilter unit may also be provided in a common inlet stream.

However, the biofilter unit should also be considered as a stand-alone unit. This type of arrangement means that during a cleaning cycle or during maintenance, a single or several biofilter units can be disconnected, while all other biofilter units are in continuous operation. It is simple to connect or disconnect the bio-filter device in such a modular system. It is also simple to increase capacity by incorporating more biofilters. Furthermore, different biofilter units may be operated in different modes simultaneously. Also, the biofilter unit may be operated sequentially. This arrangement according to the invention enables efficient operation and also enables purified water to be returned to the fish farming tanks with a higher overall yield. It should also be noted that the contaminated water stream and the residues separated in the biofilter unit may be fed to a pre-filter unit which is only used for the whole module of the biofilter unit.

Furthermore, the invention relates to a fish farming system comprising a fish farming tank and a general recirculation loop, which comprises first a pre-filter (e.g. a disc filter or a cartridge filter) capable of filtering out contaminants intended to be sent into the wastewater and further comprises a recirculation of water (and some residues), and wherein the recirculation loop comprises a subsequent biofilter unit or a biofilter module system according to the invention, which biofilter system has one or more regenerative filter units with a regenerative recirculation loop. The regenerative filter device may also be in the form of a disc filter or a cartridge filter. Also, these filters may be considered polishing filters.

Furthermore, according to another embodiment, the fish farming system further comprises means for aerating and separating the carbon dioxide before the general recirculation loop is completed and the purified aerated water is returned to the fish farming tank.

Furthermore, the invention relates to a method for operating a biofilter unit according to the invention, wherein the method comprises pumping liquid, thus water and possible residues and filter media, sequentially through the at least one vertical tube from the bottom of the vessel up to the top of the vessel over a time frame. As an example, this cleaning sequence may be performed, for example, every 30 minutes, up to every 2 to 3 hours. Furthermore, the cleaning sequence may last from 1 minute to 5 minutes each time. Likewise, the method according to the invention enables the operation of the biofilter unit according to the invention to simulate both moving bed filters and fixed bed filters in one operating cycle.

In addition to the above advantages, the biofilter unit and the possible modules according to the present invention allow a simple backwashing operation without generating large amounts of waste products. In addition, this configuration also provides 100% control over the washing of the entire bed of elements when backwashing is performed.