DE9304306U1 - Biological pond filter using marsh and aquatic plants based on the principle of food competition and oxygen enrichment - Google Patents

Description

Biological pond filter using marsh and aquatic plants based on the principle of food competition and oxygen enrichment

State of the art

Every garden owner who has ever created a pond in his garden will soon be familiar with the problem of increased algae formation and filamentous algae growth and the associated clouding of the water.

The idea that a pond filter can help quickly comes to mind. Artificially created ponds often have a water inlet that usually trickles over several artificial or natural dams (cascades), so that the moving water is naturally enriched with oxygen and supplies the pond with it. An electric pump is used to pump the pond water from a deeper part of the pond to the water inlet or a "source" (artificial water outlet). If the pump is very powerful, it can also supply a bio-mechanical pond filter.

These filter systems are expensive technical devices and you must not forget to maintain and clean them regularly. The use of chemicals is also promising at first. The dead remains that remain in the pond water serve as a nutrient base for the newly developing plankton. The cycle of death is created. Strong algae or plankton formation causes the oxygen content of the pond water to drop, especially at night. This creates the so-called "oxygen hole". Sensitive organisms die.

More and more pond owners are opting for a biological/mechanical filter type. These filters work with a two-stage process to clean the pond water:

The first stage consists of brushes or foam mats arranged closely together to hold back coarse contaminants.

The second stage consists of microorganisms that live on porous material and feed on water contaminants such as fish excrement and plant residues. They urgently need water that contains a high level of oxygen to convert the water contaminants into plant food.

These filter stages described above are located one behind the other or one above the other in a large plastic housing that is equipped with a water inlet and a water outlet. The large and unsightly filter unit is usually hidden in the water, in the ground or in a place outside the pond. However, it must always be accessible in order to be able to clean the filter stages, otherwise larger contaminants will clog the entire filter.

The first filter stages also need to be cleaned regularly or even replaced, because the foul-smelling rotting processes that occur in the impurities retained have a negative impact on the water quality and hinder the work of the microorganisms. Clear drinking water is used to clean these brushes or foam mats, which leads to an unnecessary increase in water consumption. Expensive supply trips are also necessary because the filter media must be replaced continuously in order to keep the filter running.

Before the contaminated water passes through the filter stages, it is sprayed through fine nozzles to ensure that it seeps through the filter media over as large an area as possible. These fine spray openings become clogged by small impurities in the water or clogged with algae deposits in a short time, so that the area of the downstream filter stages is no longer sprayed. This causes the microorganisms to die and the filter results are no longer adequate.

The microorganisms in the second filter stage are gathered on a granulate-like, porous material in order to come into contact with the contaminated water over as large an area as possible. In order for these little helpers to do their job satisfactorily, they depend on a high oxygen concentration in the water, but the path between the oxygen-producing roots of the pond plants and the microorganisms in the filter is long and results in losses for the oxygen in the water.

Task

The invention specified in claim 1 is based on the task of creating a biological pond filter that makes use of the way marsh and aquatic plants live and their fast-growing plant roots. This means that microorganisms settle in the immediate vicinity of the oxygen-producing plant roots, which need this oxygen as a basis for life in order to clean the pond water of dead material and fish excrement. With the help of the oxygen, the microorganisms convert the dead material etc. into nutrients that are absorbed by the plant roots. Because the nutrients that the plant roots need are also needed by the algae and plankton, this is referred to as the principle of food competition.

The structure of this natural pond filter must be such that the oxygen-producing plant roots and the microorganisms must be in close proximity to each other in order to achieve optimal filter results from this natural symbiosis.

The pond filter must be fully integrated visually and mechanically into the pond landscape after the planting and growth phase of the various marsh and aquatic plants has been completed.

The pond filter must be equally suitable for ponds with and without an artificial water inlet.

The pond filter must be designed in such a way that it can be adapted to any pond size with just a few simple steps. Cleaning or replacing individual filter stages must also be avoided during the entire service life of the pond filter.

Advantages

This invention ensures that a biological, natural pond filter delivers the best possible filter results without the help of chemical additives and without cleaning or replacing filter stages. It cannot be recognized as a filter system due to its natural and varied planting.

Plant boxes, the dimensions of which can be changed with a simple hand movement, accommodate the various root-forming marsh and aquatic plants. To support these plants in their growth and the associated root formation, each box to be planted is divided into six individual cavities that give the young plants the support they need.

The partitions between the six individual cavities are made of natural coconut fiber. These pressed coconut mats with a large surface area have a very coarse-meshed, net-like structure in which the fast-growing plant roots immediately find a secure hold and a nutrient-rich environment.

The thick walls of the pressed coconut mats provide the microorganisms with the optimal space to live in the immediate vicinity of the oxygen-producing plant roots. The open-pored structure of the coconut mats offers the ideal ratio of water flow rate and surface area for the settlement of microorganisms.

The basic equipment of the natural pond filter system consists of 10 filter boxes, with two filter boxes arranged next to each other forming a filter stage. Depending on the size of the pond and the cross-sectional dimensions of the watercourse, the natural filter system can easily be expanded by adding grid boxes, both in width, height and length.

In the normal standard version of the bio pond filter, three filter stages are equipped with oxygen-producing aquatic and marsh plants. Of the other two filter stages, one is filled with coarse gravel and the other with peat, which has a positive effect on the acid balance of the pond water. The gravel is also roughly cleaned and microorganisms settle there.

An example of the natural pond filter system shows the order of the filter stages as follows:

Flow direction of the water inlet

Marsh sedge

Coarse gravel

Marsh iris

peat

Braided rush

This open filter system does not need coarse, upstream filter stages due to its natural flow openings, because it does not clog as quickly as standard, closed filter boxes.

The water finds a free path for itself and washes around the oxygen-producing plant roots and the attached microorganisms at a slow, natural flow rate, so that a high-performance pump is not required. A simple, small pump is sufficient, and does not have to do anything other than let a small amount of water run steadily at a natural flow rate against the natural bio-filter.

There is no need for expensive and cumbersome supply trips that would otherwise be necessary to purchase dirty or used filter media.

If an artificially created pond is to be equipped with this new natural bio-filter system, a small water inlet must first be installed. Such an inlet is often already present in ponds in order to increase the oxygen content in the pond water, whereby the water cascades over small weirs and can absorb the oxygen from the air. The more beautiful appearance of the pond landscape with a small inlet or even a "spring" (artificial water outlet) also justifies the installation of a water inlet.

If it is not possible to install a water inlet in order to use the natural bio-filter in smaller commercially available plastic ponds, their kidney shape often means that there is a place directly in the pond where the filter can be positioned. The water surface of these ponds is usually divided into a large water area with a greater water depth and a small area with a lower water depth. The bio-filter system can do its work in this small area with the help of a small, energy-saving pump.

Description of the invention:

An embodiment of the invention is explained using Figures 1 to 7.

Show it :

Fig. 1 Pond filter boxes in the water inlet of a pond as a perspective and

Side view as a sectional drawing Fig. 2 Detailed view of the pond filter boxes as a perspective and

Sectional drawing
Fig. 3 Perspective of the pond filter boxes from Fig.2 in

Partial planting situation
Fig. 4 Arrangement variants (ae) of the pond filter boxes in the water inlet

of a pond as sectional drawings Fig. 5 Construction and handling principle for adaptation to the cross section

the water inflow of a pond
Fig. 6 Illustration of the plug-in hook principle of the pond filter boxes

and overall view of a pond filter box before assembly Fig. 7 Construction and handling principle of the plant root holder and its position in the pond filter box

In Fig.1, (1) indicates the pond filter boxes that are located in the water inlet (2) of the pond (3). Here you can see the standard arrangement (see also Fig.2) of the 10 pond filter boxes (1), i.e. five rows of two pond filter boxes (i) are flowed through by the pond water after a water pump (6) pumps the pond water through a water pipe (5) to the artificial water outlet (4).

In Fig.2, plant holders (7) are used in some pond filter boxes (i). These plant holders (7) are penetrated by the oxygen-producing roots of the marsh and aquatic plants (8) (see Fig.3) and at the same time serve as a habitat for the microorganisms. The plant holders (7) are made of water-permeable, pressed, slightly compressed coconut fiber mats and are inserted into one another (see Fig.7) in such a way that they give the plant roots a secure hold. The pond filter boxes (i) are divided into individual plots (15) by plant holders (7).

In Fig.3, the two rows of pond filter boxes (i) are filled with marsh and aquatic plants^) which are provided with plant holders (7). Of the two rows that are not planted, one is to be filled with coarse gravel (9) and the other with peat (10).

In Fig.4, various possible cross sections (a-e) of water inlets (2) can be seen. The water inlets (2) differ in both their width and their water depth. The pond filter boxes (i) are below the water surface (i). It can be seen in the cross sections (b+e) that the height of the pond filter boxes (i) can be adapted to the water depth. If the water depth is too deep for a row of pond filter boxes (i), double rows can be used as in the cross sections (c+d). Rows of three (a, b+c) can also be used.

Fig.5 shows the different phases and options for assembly and the two basic shapes of the pond filter boxes(i) that are necessary to fill a complete water inlet(2) with the pond filter boxes(i) in a form-fitting manner. The pond filter boxes(1) are cut to the right size using sturdy scissors(11).

In the detailed views of the pond filter boxes (i) in Fig. 6, the plug-in hook system (12) is shown, with which it is possible to connect the side walls (13) of the pond filter boxes (i) to the base (14) in the desired positions. In the overall view of a pond filter box (1) that has not yet been put together, the base (14) can be clearly distinguished from the side walls (13) and is connected to one another by film hinges (16).

Claims (8)

Protection claims 1. Biological pond filter using marsh and aquatic plants based on the principle of food competition and oxygen enrichment characterized, that pond filter boxes (i), through which pond water slowly flows, are provided with plant holders (7) made of lightly pressed coconut fibers, which divide the pond filter boxes (i) into individual plots (15) for the planting of young plants. 2. Biological pond filter according to claim 1 characterized, that the biological pond filter consists of at least 10 pond filter boxes (i) that are positioned in the water inlet (2) of the pond or directly in the pond itself, and that the pond filter boxes (i) equipped with marsh and aquatic plants (8) are flowed through by slowly flowing pond water, so that it is sufficient to use an energy-saving pump (6) with a low flow rate. 3. Biological pond filter according to claim 1 and 2 characterized, that the pond filter boxes (1) can be adapted to any pond size and also to any water inlet cross-section [Fig.4 a-e], and that the size and shape of the pond filter boxes (i) can be changed using a hook system (12) that allows the side walls (13) of the pond filter boxes (i) to be hooked to the base (14) [Fig.6], so that the bases (14) of the pond filter boxes (1) can form-fit the cross-sectional shapes of the different water inlets (2) [Fig.4 a-e], that during this process of adapting the pond filter box shape, any protruding edges of the side walls (13) and the base (14) are cut off with sturdy scissors (11), and that after this adaptation, the plant holders (7) can also be adapted to the different pond filter boxes (i) by cutting them to size with sturdy scissors (11). become. 4. Biological pond filter according to claim 1 to 3 characterized, that the biological pond filter can be easily adapted to an increase or change in pond size by adding additional pond filter boxes (i), that the pond filter boxes (i) of different water depths in the water inlets (2) [Fig.4 a-e] can be adjusted by placing them one on top of the other if the water depth is greater [Fig.4 c+d] or by cutting off the upper edge of the pond filter boxes (i) with a sturdy pair of scissors (11) if the water inlets (2) are low [Fig.4 b+e], that the upper edge of the pond filter boxes (i) is always below the water surface (16), and that when the pond filter boxes (i) are placed one on top of the other, the lower pond filter boxes (i) are also equipped with plant holders (7) made of lightly pressed coconut fibers, which thereby form an enlarged surface for the plant roots to attack. 5. Biological pond filter according to claims 1 to 4 characterized, that the biological pond filter in its simplest version [Fig.3] has five rows of two pond filter boxes (i), of which three rows of two are filled with marsh and aquatic plants (8) and of the other two rows of two, one is filled with peat (10), which ensures a regulated acid balance of the pond water and the other row of two pond filter boxes (i) is filled with coarse gravel (9). 6. Biological pond filter according to claims 1 to 5 characterized, that this open, natural filter system, thanks to its wide flow openings, does not depend on coarse, upstream filter stages. 7. Biological pond filter according to claims 1 to 6 characterized, that the plant supports (7) are made of coconut fibers that are almost impervious to water, that the plant supports (7) have a very long lifespan and are proven not to be decomposed even by salty sea water, and that the coconut fibers used as plant supports (7) are lightly pressed and made dimensionally stable with natural rubber. 8. Biological pond filter according to claims 1 to 7 characterized, that the pond filter boxes (i) are made of environmentally friendly plastic with a high recycled content, that the pond filter boxes (i), when they are not yet assembled, are delivered as mats consisting of a base (14) and four side walls (13), whereby the side walls (13) are connected to the base (14) by means of film hinges (16) [Fig.6], and that this construction facilitates the transport and assembly of the biological pond filter.