RU69698U1 - BIOCOMPLEX - Google Patents

Abstract

The utility model relates to agriculture and is intended for the disposal of animal waste, cultivation and processing of any greenhouse crops, the production of carbon dioxide, as well as solid and liquid organic fertilizers. The task to which the proposed biocomplex is directed is the disposal of livestock farms waste and increasing the economic indicators of the biocomplex. The problem is solved due to the fact that the biocomplex includes a multi-tier greenhouse with heating, lighting, irrigation and ventilation systems. The heating system is represented by digesters between which there are greenhouses for growing vegetables and mushrooms, in addition, the biocomplex is equipped with a mini thermal power station and a container for carbon dioxide, rooms for processing products and canning, a warehouse-refrigerator. The multi-tier greenhouse is equipped with mobile platforms for its maintenance. The biocomplex is two-story. 1 s.p.ph., 3 d.p.ph.

Description

The utility model relates to agriculture and is intended for the disposal of animal waste, cultivation and processing of any greenhouse crops, the production of carbon dioxide, as well as solid and liquid organic fertilizers.

Currently, green projects for the industrial utilization of agricultural waste are relevant. Thus, it is optimal to place the biocomplex near any livestock farm.

Known biocomplex according to the patent of the Russian Federation No. 2148828, in which it is possible to simultaneously grow plant and animal products using waste-free technology. The biocomplex includes a greenhouse with a reservoir connected with the house.

However, such a biocomplex is very energy intensive and, as a result, the products are quite expensive.

The closest technical solution to the proposed biocomplex is the "Biocomplex Muravsky PA" according to the patent

No. 2184440, which includes a greenhouse with hot and cold water supply, ventilation systems with automatic control units and a reservoir. The greenhouse beds are located on the load-bearing beams above the pond, made in the form of rising terraces and form isolated compartments for growing plants with the corresponding microclimate in a single heat volume, poultry compartments are arranged along the lateral and internal cavities of the beds, and cultivators are arranged below the sides of the reservoir vermicompost.

A disadvantage of the known biocomplex is the high cost of the final products, since the main costs go to energy.

The task to which the proposed biocomplex is aimed is the disposal of livestock farms waste, increasing the economic indicators of the biocomplex.

The problem is solved due to the fact that the biocomplex includes a multi-tier greenhouse with heating, lighting, irrigation and ventilation systems. The heating system is represented by digesters between which there are greenhouse rooms for growing vegetables and mushrooms, in addition, the biocomplex is equipped with a mini thermal power station and a container for carbon dioxide, rooms for processing products and canning, and a warehouse-refrigerator. The multi-level greenhouse is also equipped with mobile platforms for its maintenance. The biocomplex is two-story.

Thus, the problem of the utility model is solved.

Figure 1 shows a general view of the biocomplex. In Fig. 2 - the plan of the first floor. Figure 3 is a plan of the second floor. Fig. 4 is a diagram of the biocomplex.

The biocomplex consists of digesters 1, equipped with collectors 2 for supplying raw materials and unloading pulp, collectors 3 for collecting biogas, which is connected to a mini TPP 4, capacity 5 for collecting carbon dioxide. Between digesters 1 there are multi-tier greenhouses 6 and multi-tiered rooms 7 for growing mushrooms. Between the tiers of the greenhouses 6 and the tiers of the rooms 7, mobile platforms 8 are arranged for maintenance. The second floor of the biocomplex is equipped with premises 9 for processing products, a refrigerator warehouse 10 and a canning section 11. Mobile platforms 8 for maintenance are located in the technological passages 12. The collector 3 for collecting biogas is connected to a mini TPP 4 through a block 13 for cleaning biogas. Mini TPP is represented by an electric generator 14 and an internal combustion engine 15.

Biocomplex works as follows.

Livestock waste, mainly manure or litter, goes to the preliminary preparation unit of raw materials (not shown in the drawing), in which they are crushed and brought to the required humidity. The remainder of the plant enters the same block.

raw materials from the greenhouse, if they are formed. The prepared raw material in the form of pulp is sent to one of the digesters 1 through the collector 2, where it is heated to the temperature necessary for the activity of thermophilic bacteria, with the help of which the bioconversion of the organic component of the pulp is carried out with the formation of biogas, which mainly consists of methane and carbon dioxide. Biogas through collector 3 enters the purification unit 13, where it is separated into methane with a minimum content of impurities and carbon dioxide. Methane enters a device 15, for example, an internal combustion engine, aggregated with an electric current generator 14, generating electricity and heat - TPP 4, and carbon dioxide in a tank 5. The generated electricity is consumed mainly for lighting the greenhouse, as well as other technological needs, and thermal energy is used to heat the incoming pulp.

Heat losses from the shells of the digesters 1, for example, forming the fence of the multi-tier greenhouse 6, heat the volume of the latter to the required level, and also heat the rooms 7, where the tiers for mushroom cultivation are located. Organic fertilizers resulting from bioconversion are separated into liquid and solid fractions. The solid fraction is the basis for the formation of soil for growing mushrooms and plants using low-volume technology, and the liquid fraction is the basis for hydroponic technology

growing plants. Surplus fertilizers may be marketable products sold on the side.

Carbon dioxide from the cleaning unit is also a component of the nutrient atmosphere for plants and is used in the required quantities in the greenhouse.

The volume of each digester 1 must correspond to the daily intake of waste, and their number should be no less than the number of days required for complete bioconversion of the daily portion of waste. In this case, a quasi-continuous disposal mode is implemented.

The methane tanks 1 can be arranged, for example, linearly in two rows, forming the side rails of the greenhouse 6 located between their inner walls. In this case, the outer walls will face towards the room 7 for growing mushrooms, in which the temperature will be kept lower than in the greenhouse. The greenhouse 6, as well as the room 7 for growing mushrooms, are vertically oriented structures, the height of each tier of which can be adjusted depending on the size of the plants grown. On each tier, individual lighting is mounted, in intensity and spectral composition corresponding to the regime of plant vegetation. With a small-scale technology for growing plants, they are planted in pallets of the required depth, filled with soil of the appropriate composition. When using hydroponic technology

- on the tiers is the appropriate equipment. Tiers 6 and 7 in the plan are partitioned so that their width (depth) allows you to carry out the necessary technological operations from platforms 8, suspended on hoists, allowing you to move the platform vertically and horizontally.

The manufactured products are delivered to the second floor, where they are processed and preserved at rooms 9 and 11, respectively. Storage of products is carried out in the skad-refrigerator 10.

The possibility of implementing a utility model with the implementation of the task is confirmed by the well-known means and methods. Thus, the possibility of implementing a utility model is confirmed.

Claims (4)

1. Biocomplex, which includes a multi-tiered greenhouse with heating, lighting, irrigation and ventilation systems, characterized in that the heating system is represented by digesters equipped with collectors for feeding raw materials and unloading pulp, as well as collectors for collecting biogas, between the digesters there are greenhouses for growing vegetables and mushrooms, in addition, the biocomplex is equipped with a mini-thermal power station, a container for carbon dioxide, facilities for processing and preserving products and a warehouse-refrigerator. 2. The biocomplex according to claim 1, characterized in that the multi-tier greenhouse is equipped with mobile platforms for its maintenance. 3. The biocomplex according to claim 1, characterized in that it is made at least two-story. 4. The biocomplex according to claim 1, characterized in that on its second floor there are rooms for processing and preserving products and a warehouse-refrigerator.