RU2163076C1 - Method and apparatus for biological conversion of plant wastes - Google Patents

Abstract

FIELD: agriculture, in particular, feed production. SUBSTANCE: method involves preparing raw material; sowing microbial culture; exposing plant wastes to pulsed thermal treatment; providing fermentation and pasteurization. Source of enzyme preparations sown into prepared raw material is mixture of cultures of microorganisms comprising yeast, bacteria and fungi producing ferments possessing amylolytic and cellulosolytic properties. Biomass obtained is subjected to fermentation and pasteurization involving pulsed heating performed 3-5 times, with following reducing of temperature to 30 C. Microorganism culture contains Sacharomyces cerevisial diataficus yeasts, Acinetobacter bacteria and Pyroporus Squamosus Endomycopsis fibuliger mycelium fungi. Apparatus has horizontal vessel mounted for rotation on hollow shaft, pressure source, recirculation airduct made in the form of pipe which connects vessel outlet end to pressure source inlet end. Airduct is equipped with fresh air supply regulating device controlled by oxygen sensor and air pressure restrictor. Vessel rotation shaft has two cantilevered hollow halves connected via heater made in the form of flat hollow member rigidly fixed to shaft halves and connected to delivery side of pressure source and recirculation airduct inlet. Outer contour of this member is configured in accordance with that of vessel inner surface and is provided with brush-type edge adapted for cleaning the vessel. Method and apparatus may be used for processing of plant wastes of different origin including plant growing wastes, flour-milling, food-processing, alcoholic and brewing industry wastes, and allows feed additives with increased protein content to be produced. EFFECT: increased efficiency in producing protein feed additives and wasteless technology. 6 cl, 1 dwg, 2 ex

Description

 The invention relates to agriculture and can be used in the feed industry in the processing of various types of plant materials, including waste from crop production, flour milling, elevator production, as well as food, alcohol and brewing industries.

Known methods for producing feed protein supplements, including the preparation of raw materials, the addition of mineral salts, fermentation of the resulting biomass with a mixture of cultures of microorganisms (yeast, fungi)
(see RU 2050142 C1, 20.12.95, SU 751385 A, 07.30.80).

 The disadvantages of the known methods include large energy costs for the implementation of the process and obtaining the finished product.

 It is also known a device for processing food and vegetable waste containing a horizontal container mounted for rotation on the hollow axis, which is both an air and steam pipe, and a pressure source (SU 1583070 A1, 07.08.80).

 In this known device, heated steam or air enters the hollow central axis and is directed along the racks into a wedge-shaped pipeline and then enters and passes through its openings through the processed mass, ensuring the flow of the process.

 The disadvantages of this known device include the complexity of its design and limited application.

The closest in technical essence is the method of preparation of feed from plant materials for farm animals, which includes grinding the raw materials, adding mineral salts, heating and keeping at heating temperature, hydrolysis of the raw material with a mixture of celluloviridine GZx with pectofoetidine GZx in an amount of 0.3-0.5% of mass of raw materials, cooling the hydrolyzate, sowing it with yeast, cultivating them under aeration, followed by drying the resulting feed, in which mineral salts are introduced into the hydrolyzate before sowing the yeast
(SU 1255096 A1, 09/07/86).

 The disadvantage of this method is the limited application.

 The problem to be solved when creating the present invention is to obtain protein feed additives from various types of waste (bran, beer pellet, distillery distillery, ground vegetable waste, such as straw, tops, etc.). The bioconversion of the feedstock should include not only the carbohydrate, but also its cellulose parts, exposed to cellulite enzymes produced by the microflora used in the process of protein biosynthesis.

 The technical result of the invention is that the protein content in the processed mass increases to 30-35%, which improves the characteristics of the protein feed additive or high protein feed in the diets of animals and birds, and provides a waste-free production process.

The technical result is achieved by the fact that a mixture of microorganism cultures consisting of yeast, bacteria and mycelial fungi producing amylolytic and cellulolytic enzymes is introduced into the prepared raw materials by inoculation as enzyme preparations, while the resulting biomass is fermented for 1-5 days while maintaining it temperature in the range 30-35 ^o C, pH in the range 4.5-6.5 and humidity within 60-75% with constant aeration and periodic or continuous stirring and the subsequent heat treatment iomassy performed its plasmolysis by heating and then dewatering it by blowing warm air of the active, the temperature does not exceed 100 ^o C. When plasmolysis biomass produce a repeating 3-5 times the pulse heating it to 70 ^o C temperature with an exposure of this temperature for 0.3 -0.5 hours and a subsequent decrease in temperature to 30 ^o C. In a mixture of cultures of microorganisms, yeast Candida scottti or Sacharomyces cerevisial diataficus, bacteria Acinetobacter, mycelial fungi Endomycopsis fibuliger are used. When using lignocellulosic plant waste, such as straw or tops, in the preparation of raw materials, these wastes are pretreated with liquid trichodermin. The finished product obtained after dehydration of biomass is directly sent to packaging or pre-granulated, and then packaged.

 The bioconversion method includes the following steps: preparation of raw materials, inoculation with a microbial culture, fermentation and pasteurization (by plasmolysis).

Before fermentation, plant waste, such as bran, is subjected to pulsed heat treatment with increasing substrate temperature from 30 to 70 ^o C with a frequency of 0.3-0.5 hours, from 3 to 5 times, then a mixed culture is sown with yeast, mycelial fungi and bacteria. The mixture consists of Candida scotti yeast, Endomycopsis and Poliporus fungi, Acinotobacter bacteria. Then the resulting biomass is heated to a fermentation temperature of 30 - 35 ^o C and incubated on the solid phase for 1-5 days. The plant substrate subjected to bioconversion should have a moisture content of 60-75%, the amount of sowing mass from 2 to 10% by volume of the substrate. Fermentation is carried out with constant or periodic mixing of the substrate, with constant aeration, the duration of the process is 1-5 days. The composition of the mineral components of the environment depends on the type of processed raw materials, but should include elements that are necessary for normal protein synthesis. The main elements of the mineral medium should be present in the nutrient medium based on 1 g of the obtained biomass: N - 80 mg, PO - 40 mg, K - 25 mg, Mg - 3 mg, Fe - 1 mg, Zn - 0.6 mg, Mn - 0.1 mg. Various biostimulants and biologically active compounds (autolysate, corn extract), individual additional trace elements (Mo, Ni, Cr, Co), etc. can be added to the medium.

Fermentation is carried out at a temperature of 30 - 35 ^o C, which is optimal for the growth and development of most microorganisms that synthesize protein.

In the fermentation process, the development of microorganisms - protein producers is monitored according to the following technological parameters:
temperature - 30 -35 ^o C
pH - 4.5 - 6.5
medium mixing - periodic or continuous
mixture humidity - 60-75%
Monitoring is carried out at least 1 time per day.

 The resulting protein-vitamin mixture after fermentation is subjected to pasteurization and dehydration.

Pasteurization is carried out by pulse heat treatment, i.e. the volume of biomass is heated to a temperature of 70 ^o C and maintained for 0.3-0.5 hours, then the temperature drops to 30 ^o C, the cycle is repeated 3-5 times. After pasteurization, the biomass is dried in the installation itself with air heated to 100 ^o C. The moisture content of the finished product is 20-25%. The finished product obtained after dehydration of biomass is directly sent to packaging or pre-granulated, and then packaged. The finished product can be used directly if the installation is located at a livestock or poultry farm.

 When bioconversion of lignocellulosic plant waste, such as straw, tops, etc., before fermentation, they are treated with a culture fluid containing bacteria and amylolytic, cellulolytic enzymes produced by them, for example trichodermin.

 Examples of the method.

 Example No. 1.

 An association of microorganisms consisting of Endomycopsis sp., Polyporus squamosus and Acinetobactor sp.

Cultivation is carried out at a temperature of 32-34 ^o C, pH 4.5-6.0 on a medium of the following composition: a mixture of rye and wheat bran (1: 1).

Preparation of grain raw materials: hydromodule (a mixture of wheat bran according to the instructions). Saccharification by its own enzymes is carried out at a temperature of 55 ^o C for 40 minutes

The composition of the mineral medium on which the fermentation process is carried out: ammonium nitrogen - 1300 mg / l; phosphorus (P ₂ O ₅ ) - 1500 mg / l; potassium - 1400 mg / l; magnesium - 210 mg / l; iron - 3.1 mg / l; zinc - 2.3 mg / l; Manganese - 1.5 mg / L.

 The fermentation process is carried out for 48 hours with constant microbiological control. The amount of protein in biomass is 42.5%.

 Example No. 2.

 The microorganism association consists of the yeast Saccharomyces cerevisiae diastaticus VKPM 1218, the fungus Endomycopsis sp. and bacteria Acinetobacter sp.

The fermentation process is carried out during aeration, the substrate humidity is 65-70%, to which, after heat treatment for 30-40 minutes at a temperature of 75 ^o C, the necessary mineral salts are added in the amounts indicated in Example No. 1. The fermentation process is carried out at pH 4.5- 5.0 and a temperature of 32-34 ^o C for 48-52 hours.

 The result is a protein feed product with a crude protein content of 45.3%.

 The proposed method can be widely applied directly to livestock complexes, poultry farms and animal feed enterprises for processing organic waste into feed additives with a given and stable chemical composition.

 To implement the method of bioconversion of plant waste, the proposed installation shown in the drawing.

 The installation is a solid-phase bioreactor consisting of a rotating horizontal fermentation tank 1 mounted on two cantilever hollow half shafts 2 and 3, connected by a flat contact heater 4, made in the form of a flat hollow element, rigidly fixed on the half shafts 2 and 3 and connected to the discharge outlet 5 the pressure source (fan) 6 and the inlet of the recirculation air duct 7. The specified heater 4 is made in the form of a hollow flat panel through which the heated air passes. The outer contour of the panel repeats the configuration of the inner surface of the fermentation tank 1 and is equipped with a brush edging 8 made of a deformable material and providing cleaning of the tank 1 from sticking particles of the fermented biomass.

 Recirculation air duct 7 has a fresh air regulator 9, controlled by an oxygen sensor 10, and a pressure limiter 11 mounted on the specified duct 7.

 In the fermentation tank 1, sealing hatches 12 are made for feeding the processed biomass into the tank 1 and unloading the finished product from the tank 1.

 The installation has a drive 13 of rotation of the fermentation tank 1, connected with the last gear system, as well as a temperature control device 14 and an oxygen meter 15.

 Installation works as follows. The components of the processed biomass through the sealing hatches 12 are fed into the fermentation tank 1, where heated air and / or steam is supplied through the hollow shaft 2. After that, the drive 13 is turned on, by which the tank 1 is driven into rotation through a system of gears. After a period of mixing and fermentation, the temperature of the supplied air by means of a temperature control device 14 rises to the temperature of pasteurization (plasmolysis), after which the finished product is unloaded through the same hatches 12. The temperature control of the circulating air and the oxygen content in it is carried out using a temperature control device 14 and an oxygen meter 15.

 Next, the cycle repeats.

Claims (6)

1. The method of bioconversion of plant waste, including preparing raw materials, adding mineral salts, introducing enzyme preparations into prepared raw materials, fermenting the biomass obtained at a stable temperature and its subsequent heat treatment, characterized in that the plant waste is subjected to pulsed heat treatment with increasing substrate temperature from 30 to 70 ^o C with a periodicity of 0.3 - 0.5 hours, 3 - 5 times, then introduced into the prepared feed by the seed as a mixture of cultures producing enzymes MicroHoo -organisms consisting of yeasts, bacteria and filamentous fungi that produce amylolytic and cellulolytic enzymes, thus obtained fermentation biomass produced for 1 - 5 days while maintaining its temperature in the range of 30 - 35 ^o C, a pH in the range 4.5 - 6, 5 and humidity in the range of 60 - 75% with constant aeration and periodic or continuous mixing, and during subsequent heat treatment of the biomass, it is pasteurized (plasmolysis) by heating and then dehydrated by actively blowing with heated air hamster, whose temperature does not exceed 100 ^o C. 2. The method according to claim 1, characterized in that during pasteurization of biomass produce repeated 3 to 5 times a pulse heating it to 70 ^o C with the exposure of this temperature for 0.3 to 0.5 hours and a subsequent decrease in temperature to 30 ^o C .  3. The method according to claim 1 or 2, characterized in that the mixture of cultures of microorganisms use Sacharomyces cerevisial diataficus yeast, bacteria, for example Acinetobacter, and mycelial fungi, for example Polyporus Squamosus, and yeast fungi, for example Endomycopsis fibuliger.  4. The method according to any one of claims 1 to 3, characterized in that when using lignocellulosic plant waste, such as straw or tops, in the preparation of raw materials, these wastes are pretreated with liquid trichodermin.  5. The method according to any one of claims 1 to 4, characterized in that the finished product obtained after dehydration of the biomass is directly sent to the packaging or pre-granulated, and then packaged.  6. Installation for bioconversion of plant waste, including a horizontal tank mounted for rotation on the hollow axis, which is both an air and steam pipe, and a pressure source, characterized in that it contains a recirculating air pipe made in the form of a pipe connecting the container output to the input pressure source, and equipped with a regulator of fresh air supply, controlled by an oxygen sensor, and an air pressure limiter, and the hollow axis of rotation of the tank consists of two cantilever hollow axles connected by a flat contact heater made in the form of a flat hollow element rigidly fixed to the axles and connected to the discharge outlet of the pressure source and the inlet of the recirculation air duct, the outer contour of the element repeating the configuration of the inner surface of the tank and equipped with a brush edging made of deformable material and providing cleaning of the tank from sticking particles of fermentable biomass.