DE202017104038U1 - Moss comprehensive greening system - Google Patents

Abstract

A moss-comprehensive greening system, in particular for anchoring to a static load-bearing element (1), in particular a bearing wall or a supporting fence, comprising - at least one substructure of at least one support profile (2) for anchoring in the static-bearing element (1); - At least one support plate (3), wherein the at least one support plate (3) is arranged on or on the at least one substructure; - At least one Moosmatte (4), wherein the at least one Moosmatte (4) on the at least one support plate (3) is arranged, - wherein the at least Moosmatte comprises at least one carrier fleece with pre-cultured mosses provided thereon; and - at least one irrigation system (5), wherein the at least one irrigation system (5) causes uniform moistening of the surface of the at least one moister mat (4).

Description

The present invention relates to a greening system according to claim 1.

description

Air pollution and air pollution, especially in city centers with high traffic volumes and high building density, through particulate matter and nitrogen oxides is a serious problem. Various approaches to solving this problem, such as reducing the speed of vehicular traffic or incorporating particulate particulate filters in automobiles, are being pursued, but have not heretofore provided the necessary reduction in particulate matter loading.

It is known that suitable greening of city centers can contribute to the reduction of particulate matter, nitrogen oxides and carbon dioxide. However, there is often a lack of space in the city centers for planting trees or shrubs. This lack of space can be counteracted by the arrangement of planted walls.

Various approaches to planted walls have been described so far. So revealed the EP 2 382 859 A2 a plant container system as part of a building, wherein plant containers are used for a construction of a wall and are at least partially filled with a plant substrate. However, it has been shown that the particulate filter effect of foliage plants is not effective enough to meet the required limits.

On the other hand, mosses have a significantly better binding effect on particulate matter. Moose can actively bind and absorb particulate matter in their metabolism. Moose absorb their food and water exclusively through the cell walls of their leaves. Because of this, mosses need no roots and no nutrient-rich subsoil for survival and growth. They feed exclusively on nutrient particles in the air.

Since particulate matter mainly consists of nitrogen compounds, it can ideally serve as a nutrient source for the moss. Thus, about half of the fine dusts consist of ammonium salts, which are absorbed as fertilizer by the mosses and converted directly into plant matter. Accordingly, mosses need no fertilizer and require little care.

The nutrient particles are absorbed by ion exchange. The moss leaves are negatively charged and occupied by H ⁺ ions. The H + ions are exchanged for ions such as ammonium. Depending on the species, damp mosses can bind between 13 and 22 grams of fine dust per square meter. In particular, mosses have an extremely large surface due to their leaflets: One cubic centimeter of moss provides 0.17 m ² surface, which can hold and bind the fine dust electrostatically.

Other benefits of Moose are its ability to store water and absorb noise due to its large surface area.

Devices that exploit the particulate matter absorption of mosses are already known. So will in the DE 20 2007 012 9291 a moss-green building board for exterior walls, wherein the moss is attached by means of an adhesive on the building boards.

From the DE 10 2013 107 786 A1 For example, a vertical plant wall is known which has wall mountable vertical support structures for plant bags and full surface vertical coverage of moss mats. The plants inserted into the plant bags grow through the Moosmatte arranged in front of it.

The DE 20 2009 007 311 U1 describes a noise protection element, in which on the noise side a Moosmatte is provided, which is irrigated via an irrigation device. The irrigation device comprises a water line with a plurality of outlet openings (for example in the form of a porous tube), which runs above the Moosmatte. The dripping water from the water pipe runs down the moss mat and keeps it moist. A disadvantage of this type of irrigation of Moosmatte is an uneven moistening of Moosmatte, so that the overhead mosses too little, the moss growing below in the mat receive too much water and thus die sooner or later. In addition, the dripping excess water must be absorbed or discharged from the underlying surface.

The invention is therefore based on the object to provide a greening system for the effective reduction of particulate matter and nitrogen oxides in the air, especially in the inner city area.

This object of the invention is achieved by a greening system with the features of claim 1. Further advantageous embodiments of the invention will become apparent from the dependent claims.

Accordingly, a moss-comprehensive greening system is provided, which is particularly suitable for anchoring to a static-carrying element, such as a load-bearing wall or a supporting fence.

• – mindestens eine Unterkonstruktion aus mindestens zwei Tragprofilen zur Verankerung in dem statisch tragenden Element;
• – mindestens eine Trägerplatte, wobei die mindestens eine Trägerplatte auf oder an der mindestens einen Unterkonstruktion angeordnet ist;
• – mindestens eine Moosmatte, wobei die mindestens eine Moosmatte auf der mindestens einen Trägerplatte angeordnet ist,
• – wobei die mindestens Moosmatte mindestens ein Trägervlies mit darauf vorgesehenen vorkultivierten Moosen umfasst; und
• – mindestens ein Bewässerungssystem, wobei das mindestens eine Bewässerungssystem eine gleichmäßige Befeuchtung der Oberfläche der mindestens einen Moosmatte bewirkt.

The present greening system comprises

• - At least one substructure of at least two support profiles for anchoring in the static-bearing element;
• - At least one support plate, wherein the at least one support plate is arranged on or on the at least one substructure;
• At least one mousse mat, wherein the at least one mousse mat is arranged on the at least one carrier plate,
• - wherein the at least Moosmatte comprises at least one carrier fleece with pre-cultured mosses provided thereon; and
• - At least one irrigation system, wherein the at least one irrigation system causes a uniform moistening of the surface of the at least one Moosmatte.

The present planting system thus comprises a moss-covered vertical (i.e., perpendicularly non-sloped) element, such as e.g. a vertical wall ensuring uniform watering adapted to the moisture requirements of the moss. It has been shown that for an effective fine dust absorption the mosses should preferably not go into a state of desiccation at any time during their life cycle. On the other hand, mosses respond to an excess of water but are also sensitive. The moisture content of the moss must therefore be fine-tuned. The presently used irrigation system now allows complete moistening of the entire surface of the Moosmatte so that the moss is at any time in its active metabolic phase.

The present irrigation system causes an exclusive irrigation or moistening of the moss surface; Irrigation of the back or bottom of the Moosmatte is neither necessary nor useful, since mosses have no roots. Also, it is preferred as an automated system and allows for needs-based irrigation.

In one embodiment of the present greening system, the at least one irrigation system comprises a plurality of openings for dispensing water, in particular nozzles, wherein the nozzles are arranged evenly spaced in or on the Moosmatte.

In a preferred variant, the irrigation system consists of one or more irrigation tubes with mist nozzles, these mist nozzles are arranged at a regular distance from each other, so that a moistening of the entire surface of the Moosmatte is effected.

The distance between the nozzles or outlet openings to each other is determined by the throw (range or irrigation circle) of the nozzles and outlet openings. Preferably, the irrigation circuits of the nozzles or outlet openings overlap, so that all areas of the Moosmatte can be watered evenly. On average, one nozzle per square meter is provided.

The water supply lines necessary for the irrigation system are preferably made of plastic, e.g. made of 16 mm polyethylene pipes. The water supply lines are laid behind or below the moss mat (i.e., between the moss mat and the support plate). The water supply lines have at predetermined locations on a web on which the nozzle head is mounted later. After laying the Moosmatte a T-cut is placed in the Moosmatte above the bridge. Subsequently, a cross adapter is placed on the bridge. Four nozzles are attached to it, which brush the moss mats against the water mist. The given places are also underlaid with 0.5-1.0 cm thick washers, so that the webs and thus the later attached nozzle heads get a sufficiently large distance to the moss wall.

In a further embodiment of the present greening system, at least one device is provided at the lower end of the support plate for collecting the water draining over the mat mat (as water guide profile). This collecting device for the running water can be provided as a gutter or gutter profile.

For irrigation of mosses or Moosmatten rainwater is preferably used. Rainwater can e.g. roof and parking areas are collected and fed to the irrigation system (e.g., by means of a pump). The water used for irrigation may have a maximum degree of hardness of 7 degrees German hardness. At higher degrees of hardness, the water can also be pre-treated with a partial desalination plant.

The amount of water used for irrigation results from the number of nozzles, the duration of irrigation and the pressure generated. So a nozzle consumes about 6 liters per hour at a pressure of 3 bar.

In a further embodiment of the present greening system, the at least one mousse mat consists of a fleece of at least two layers. The moss plants are fused on the fleece surface. In particular, the moss mat consists of a carrier fleece with young moss growing on it (pre-cultivated), which due to their adhesive organelles on the fleece hold tight and so can grow together with the nonwoven surface.

In a variant, a first layer comprises a water storage fleece, in particular of polyacrylates or polyethylene. Such webs have a basis weight of 500-1000 g / m ² , preferably from 600 to 800 g / m ² .

At least one further, second layer in the form of a filament fabric is arranged on this first layer. The filament web is e.g. made of polyamide threads, which are sewn onto the water storage fleece.

The material thickness of the nonwoven is in a range between 10 and 50 mm, preferably 15 and 30 mm.

The at least one pre-cultured Moosmatte is mounted on the at least one support plate by means of suitable Befestigungslemente. Suitable fastening means for this purpose are e.g. Stainless steel tack needles or stainless steel taps.

In a particularly preferred embodiment of the present greening system, the moss mat comprises mosses selected from the group comprising Rhacomitrium cauesens, Ceratodon purpureus, Bryum argenteum, Bryum capillare, Brachythecium rutabulum, Hypnum filliformis, Polytrichum commune, Polytrichum formosum, Polytrichum juniperinum, Tortula ruralis, Tortula muralis, Leucodon sciuroides.

The presently preferred mosses are characterized by a particularly good dry resistance, urban climate resistance, as sunny as possible contracts (shady layers are always preferable) characterized.

In a variant of the present greening system, an aluminum composite panel is used as the support plate. Such aluminum composite panels are advantageous because it is hardly subject to thermal stress.

The carrier plate is fastened on the carrier profile by means of suitable fastening elements. The support plates are fastened to the support profiles with rivets or screws (stainless steel). If necessary, a static calculation must be used.

As mentioned above, the at least one substructure consists of at least two support profiles, in particular of at least two mutually spaced carrier elements. It can also be provided T or L profiles. The support profiles preferably extend vertically and at a predetermined distance parallel to one another, wherein the distance between the support profiles is predetermined by the static calculation.

The support profile is fastened by means of suitable anchoring elements to the supporting element. These anchoring elements may be, for example, suitable drill bits screws. The entire substructure will comply with the standard: DIN 18516 . DIN EN 13830 and DIN 18351 rear ventilated facade built.

The present invention will be explained in more detail with reference to an embodiment shown in the figure. In detail, the figures show:

1 a cross-sectional view of an embodiment of the greening system according to the invention,

2 a diagram showing the reduction of particulate matter by different species of moss.

In 1 Figure 3 is a side cross-sectional view of one embodiment of the present greening system B shown. The greening system B is here for anchoring to a load-bearing wall 1 provided as a statically supporting element.

The greening system B comprises a substructure consisting of a supporting profile 2 from several carrier elements 2a , a support plate 3 , a moss mat 4 and an irrigation system 5 ,

Because support profile 2 consists of several parallel arranged aluminum tubes as vertical support elements 2a , The anchoring of the supporting profile in the load-bearing wall 1 takes place by means of suitable anchoring elements, which are provided for example at a distance of 50 cm from each other.

On the aluminum tubes as carrier elements 2a is the carrier plate 3 attached, on which in turn the pre-cultivated Moosmatte 4 is arranged.

The Moosmatte 4 consists of a water storage fleece made of polyacrylates or polyethylene with a weight per unit area of 800 g / m ² , over which a Filamentgelege (loop fabric) is sewn from polyamide yarns. Both materials are UV stabilized. The fleece has a low weight and a normal flammability. The material thickness of the fleece is about 15 mm.

On the surface of the fleece, the moss plants are anchored so as to obtain the precultivated Moosmatte. In the grown state is due to the high water storage capacity of the moss a basis weight of the moss mat of received over 2 kg / m ² . In the fully overgrown and water-saturated state, the mat can weigh up to 20 kg / m ² .

The Moosmatte 4 is on the carrier plate 3 fastened by means of staple needles or plumbing screws.

Moistening the Moose of the Moosmatte 4 is through an irrigation system 5 guaranteed. The irrigation system 5 consists of several irrigation pipes, which are arranged at regular intervals nozzles for water discharge. Due to the regular arrangement of the nozzles, a uniform moistening of the entire surface of the moss mat is ensured.

The distance between the nozzles or outlet openings is determined by the irrigation circuit of the nozzles. On average, one nozzle per square meter is provided.

The one for the irrigation system 5 necessary water supply lines consist of 16 mm polyethylene pipes. The water supply lines are laid behind or below the mat mat (ie between mat mat and carrier plate). The water supply lines have at predetermined locations on a web on which the nozzle head is mounted later. After laying the Moosmatte a T-cut is placed in the Moosmatte above the bridge. Subsequently, a cross adapter is placed on the bridge. Four nozzles are attached to it, which brush the moss mats against the water mist.

At the lower end of the carrier plate 3 is a gutter profile 6 as a catcher for the over the Moosmatte 4 provided running water. The effluent water may, for example, be pumped into the irrigation system using a suitable pump 5 be returned and used again.

For irrigation rainwater is preferably used, which can be collected for example from roof and parking areas and in the irrigation system 5 is introduced.

Since mosses do not have roots, they absorb their food directly through the cell walls of the leaves by ion exchange. Mosses have an extremely large surface due to their dense platelets, which can bind the fine dust. The ammonium nitrate contained in the fine dust up to 50% is directly absorbed by the mosses, metabolized and thus converted into plant matter. Furthermore, moss leaves are populated by a variety of bacteria that can degrade organic particulate matter such as soot and tire abrasion. The metabolic products of the bacteria are in turn usable for mosses. In the sum of the metabolic processes of mosses and bacteria about 75% of the fine dust can be eliminated. The remnants of insoluble inorganic dusts are retained by the mosses, with the dusts directly growing into the mosses.

The ability of different moss types to fine dust binding is in the diagram of 2 shown. Here, the uptake of Pb ²⁺ ions from different moss species at different water saturation is compared. It shows that the ability for fine dust binding depends to a large extent on the water saturation of mosses.

So it is unsurprising that the fine dust binding at a water saturation of about 0% (ie dried state of the moss) is formed only very low, whereas at a water saturation between 40-50%, a binding of Pb ^{2+ reaches} between 20 and 30% becomes. A water saturation of 100% reduces the Pb ²⁺ binding to 15 to 20%. An optimally adjusted water saturation of the mosses is therefore necessary and desirable for the most efficient fine dust binding.

Further experiments on fine dust binding revealed that moist mosses can bind 13-22 g of fine dust per square meter, depending on the type.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• EP 2382859 A2 [0004]
• DE 2020070129291 [0009]
• DE 102013107786 A1 [0010]
• DE 202009007311 U1 [0011]

Cited non-patent literature

• DIN 18516 [0035]
• DIN EN 13830 [0035]
• DIN 18351 [0035]

Claims (12)

A moss-based planting system, in particular for anchoring to a static load-bearing element ( 1 ), in particular a supporting wall or a supporting fence, comprising - at least one substructure comprising at least one supporting profile ( 2 ) for anchoring in the statically supporting element ( 1 ); - at least one support plate ( 3 ), wherein the at least one support plate ( 3 ) is arranged on or at the at least one substructure; - at least one mousse mat ( 4 ), wherein the at least one mousse mat ( 4 ) on the at least one support plate ( 3 ), wherein the at least one moss mat comprises at least one carrier fleece with pre-cultured mosses provided thereon; and - at least one irrigation system ( 5 ), wherein the at least one irrigation system ( 5 ) a uniform moistening of the surface of the at least one Moosmatte ( 4 ) causes. Greening system according to claim 1, characterized in that the at least one irrigation system ( 5 ) Comprises nozzles or openings for dispensing water, wherein the nozzles or openings for dispensing water are arranged evenly spaced in or on the Moosmatte. Greening system according to one of the preceding claims, characterized in that the at least one irrigation system ( 5 ) comprises an irrigation tube with mist nozzles. Greening system according to one of the preceding claims, characterized in that at the lower end of the carrier plate at least one device ( 6 ) is provided for collecting the effluent over the Moosmatte water. Greening system according to claim 4, characterized in that the collecting device ( 6 ) is provided for the running water as a gutter or gutter profile. Greening system according to one of the preceding claims, characterized in that the at least one moss mat ( 4 ) consists of at least two layers. Greening system according to claim 6, characterized in that at least one layer comprises a water storage fleece, in particular of polyacrylates. Greening system according to claim 6 or 7, characterized in that at least one further layer comprises a Filamentgelege. Greening system according to one of the preceding claims, characterized in that the at least one moss mat ( 4 ) on the at least one support plate ( 3 ) is attached using suitable fasteners. Greening system according to one of the preceding claims, characterized in that the moss mat ( 4 ) Moose selected from the group comprising Rhacomitrium cauesens, Ceratodon purpureus, Bryum argenteum, Bryum capillare, Brachythecium rutabulum, Hypnum filliformis, Polytrichum commune, Polytrichum formosum, Polytrichum juniperinum, Tortula ruralis, Tortula muralis, Leucodon sciuroides. Greening system according to one of the preceding claims, characterized in that the at least one support plate ( 3 ) is an aluminum composite panel. Greening system according to one of the preceding claims, characterized in that the supporting profile is fastened by means of suitable anchoring elements to the supporting element.

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