RU224421U1 - Non-woven eco-friendly biodegradable phytomaterial made from moss and vascular plants for air purification - Google Patents

Abstract

The utility model relates to non-woven filter materials used for air purification. Non-woven eco-friendly biodegradable phytomaterial made from moss and vascular plants for air purification contains Sphagnum moss and wheat sprouts Triticum aestivum L. The phytomaterial is held together by the root system of a vascular plant grown hydroponically. Additionally may contain Eruca sativa L or Lepidium sativum. The new eco-friendly biodegradable non-woven phytomaterial has enhanced air-purifying properties. 2 salary f-ly, 2 ill., 3 pr.

Description

The utility model relates to non-woven filter materials used for air purification.

With the continuous development of cities, the environmental situation in them becomes more and more difficult. Atmospheric air pollution is becoming one of the serious risk factors for human health, the most dangerous pollutants are metal-containing PM ₁₀ and PM _2.5 , and the most striking manifestation of global warming is the strengthening of the urban heat island effect. In the process of economic development, water, air and food are the three basic elements of human life and health. The technical solution of the utility model relates to nature-like technologies; the developed non-woven phytomaterial can be used for urban artificial landscaping and indoor air purification. The material is based on sphagnum moss (Sphagnum) and vascular plants. It retains all the positive properties of moss, for example, absorbing water when watering, and the mass water absorption of the substrate can be 10:1-15:1), as well as antibacterial and antifungal properties that prevent diseases of the plant root system, increase the survival rate of seedlings and accelerate their development . Moreover, the material is completely biodegradable and environmentally friendly.

An environmentally friendly bulk non-woven material [1] is known, made from a chaotic fibrous mixture of seaweed (Zostera marina) and low-melting synthetic fiber, bonded with a partially melted polymer of the latter, located mainly at the points of contact of low-melting synthetic fibers with each other and the rest of the fibers of the chaotic fibrous mixture, into which Sphagnum moss (Sphagnum) or cuckoo flax moss (Polytrichum commune) may be added. The disadvantage is that the material is not intended for air purification and is not completely biodegradable due to the content of synthetic fibers; it is not environmentally friendly enough and, in addition to phytocomponents, contains synthetic fibers.

Modules made of sphagnum moss are known [2], which are a substrate made of synthetic non-woven moisture-resistant material and a fine mesh on which the moss is fixed. When air passes through the sphagnum moss modules, fine dust is filtered, the air is cooled and humidified. The disadvantage of such modules is that they are not environmentally friendly due to the use of a substrate made of synthetic non-woven moisture-resistant material and fine mesh.

A device is known [3], containing a filter block consisting of an air-permeable filter substrate of mineral fiber or glass fiber, on which live moss is fixed; it belongs to a species selected from the group of species consisting of c (soil toothed moss), Tortula muralis (wall or roofing tortuous jagged moss), Racomitrium canescens. (gray tooth moss), Ceratodon purpureus (purple tooth moss), Brachythecium albicans (white short box moss) and Pseudoscleropodium purum (green stem moss). These types of moss have particularly high resistance to dehydration, high light resistance, sufficient resistance to hard water and a particularly pronounced ability to accumulate fine dust compared to other types. In the case of Syntrichia raralis, there is also tolerance to salt water. This makes it possible for the filter device to operate particularly reliably in relation to changing environmental influences and extreme conditions on site. In another embodiment of the invention, the filter unit also contains at least one other living plant, which preferably belongs to the genus Spinacia or Eucalyptus. This modification allows for improved absorption of nitrogen oxides from the air. The disadvantage of such a module is the presence of a non-ecological backing made of glass wool or mineral fiber; also, such material itself can become a source of air pollution due to destruction during air filtration and the entry into purified air of fine particles of mineral fiber or glass fiber, which carry significant health risks, therefore the product contains CityTree [4] the efficiency of these PM ₁₀ filter units is from 1.5% to 15% and up to 0.8% of nitrogen oxides.

The technical objective of the proposed utility model is to create an environmentally friendly biodegradable non-woven material based on moss and vascular plants for use as a filter for air purification.

This problem is solved by the fact that the proposed environmentally friendly non-woven material contains moss, held together by the roots of vascular plants. Due to the fact that the material does not contain any synthetic organic or inorganic materials, it is completely environmentally friendly, biodegradable and is highly effective in purifying the air from fine impurities (metal-containing PM ₁₀ and PM _2.5 ) and volatile organic compounds, including formaldehyde. The material does not require additional reinforcing and filtering layers. Sphagnum moss is used as moss, together with which vascular plants are grown using hydroponics. Triticum aestivum L. (spring wheat), Lepidium sativum (cress), Eruca sativa L (arugula) can be used as vascular plants.

The technical result of the proposed utility model is the creation of a new environmentally friendly biodegradable non-woven phytomaterial with enhanced air-purifying properties. This new material retains its properties.

The technical result is achieved due to the fact that the non-woven eco-friendly biodegradable phytomaterial made from moss and vascular plants, according to the utility model, contains Sphagnum moss and wheat sprouts Triticum aestivum L, is fastened with the root system of the vascular plant, and is grown by hydroponics.

In addition, the non-woven eco-friendly biodegradable phytomaterial made from moss and vascular plants, according to the utility model, contains Sphagnum moss and wheat sprouts Triticum aestivum L, secured by the root system of the vascular plant, grown hydroponically and additionally contains Eruca sativa L.

In addition, the non-woven eco-friendly biodegradable phytomaterial made from moss and vascular plants, according to the utility model, contains Sphagnum moss and wheat sprouts Triticum aestivum L, secured by the root system of the vascular plant, grown by hydroponics and additionally contains Lepidium sativum.

The essence of the utility model is illustrated in Fig. 1, which shows the phytomaterial.

The proposed eco-friendly biodegradable non-woven phytomaterial is made of a mixture of sphagnum moss (Sphagnum), fastened with the roots of vascular plants of wheat Triticum aestivum L. As vascular plants, the phytomaterial may contain Triticum aestivum L. (spring wheat), Lepidium sativum (cress), Eruca sativa L (arugula). The presence of moss and vascular plants in the material allows you to create an environmentally comfortable atmosphere and humidity in your home, stabilize the thermal regime and purify the air. In general, the fiber thickness is 10-50 mm.

The implementation of the utility model can be illustrated by the following examples

Example 1

Pre-prepared and germinated wheat seeds were placed in a plastic container containing a base, four walls and a space for growing phytomaterial. Crushed sphagnum moss was laid on top in a layer 10 mm thick. Then the space for growing phytomaterial was filled with liquid mineral fertilizer for growing plants. The top was covered with transparent plastic film and left for the seeds to germinate. After seed germination, the film was opened and the phytomaterial was watered daily. Wheat sprouts were trimmed to ensure a module thickness of 50 mm. The material was tested on a specially created installation shown in Fig. 2, consisting of a space for placing a phytomodule represented by phytomaterial, a phytolamp, an irrigation system and a sensor for measuring air quality. The area of material used was 0.6 square meters, cleaning was carried out within 4 hours in a room with an area of 30 square meters. The cleaning efficiency for metal-containing PM ₁₀ and PM _2.5 was 65%, volatile organic compounds - 25%, formaldehyde - 20%.

Example 2

Pre-prepared and germinated wheat and arugula seeds were placed in a plastic container containing a base, four walls and space for growing phytomaterial. Crushed sphagnum moss was laid on top in a layer 10 mm thick. Then the space for growing phytomaterial was filled with liquid mineral fertilizer for growing plants. The top was covered with transparent plastic film and left for the seeds to germinate. After seed germination, the film was opened and the phytomaterial was watered daily. The final thickness of the phytomaterial was 50 mm. The material was tested on a specially created installation shown in Fig. 2, consisting of a space for placing a phytomodule represented by phytomaterial, a phytolamp, an irrigation system and a sensor for measuring air quality. The area of material used was 0.6 square meters, cleaning was carried out within 4 hours in a room with an area of 30 square meters. The cleaning efficiency for metal-containing PM ₁₀ and PM _2.5 was 70%, volatile organic compounds - 25%, formaldehyde - 20%.

Example 3

Pre-prepared and sprouted seeds of wheat and watercress were placed in a plastic container containing a base, four walls and space for growing phytomaterial. Crushed sphagnum moss was laid on top in a layer 10 mm thick. Then the space for growing phytomaterial was filled with liquid mineral fertilizer for growing plants. The top was covered with transparent plastic film and left for the seeds to germinate. After seed germination, the film was opened and the phytomaterial was watered daily. The final thickness of the phytomaterial was 50 mm. The material was tested on a specially created installation shown in Fig. 2, consisting of a space for placing a phytomodule represented by phytomaterial, a phytolamp, an irrigation system and a sensor for measuring air quality. The area of material used was 0.6 square meters, cleaning was carried out within 4 hours in a room with an area of 30 square meters. The cleaning efficiency for metal-containing PM ₁₀ and PM _2.5 was 75%, volatile organic compounds - 25%, formaldehyde - 25%.

Literature

1. RU 134 935 U1, publ. November 27, 2013.

2. RU 2 798 522 C1, publ. 06/23/2023.

3. DE 10 2017 207 364 A1, publ. 08.11.2018.

4. Villani, MG; Russo, F.; Adani, M.; Piersanti, A.; Vitali, L.; Tinarelli, G.; Ciancarella, L.; Zanini, G.; Donateo, A.; Rinaldi, M.; et al. Evaluating the Impact of a Wall-Type Green Infrastructure on PM ₁₀ and NOx Concentrations in an Urban Street Environment. Atmosphere 2021, 12, 839. https://doi.org/10.3390/atmos12070839.

Claims (3)

1. Non-woven eco-friendly biodegradable phytomaterial made from moss and vascular plants for air purification, containing Sphagnum moss and Triticum aestivum L wheat sprouts, held together by the root system of a vascular plant grown hydroponically. 2. Non-woven eco-friendly biodegradable phytomaterial made from moss and vascular plants according to claim 1, characterized in that it additionally contains Eruca sativa L. 3. Non-woven eco-friendly biodegradable phytomaterial made from moss and vascular plants according to claim 1, characterized in that it additionally contains Lepidium sativum.