RU2048118C1 - Method and device for making coarse fodder - Google Patents

Abstract

FIELD: agricultural engineering, fodder production. SUBSTANCE: method involves loading raw materials into a container, transporting and placing them into containers, wetting, introducing dissolved chemical reagents, heat treatment, aeration, fermentation and yeasting. The raw material is transported and placed in the chamber by a stream of air while wetting, fermentation and yeasting are carried out stage by stage. The device comprises cylindrical chamber 3, a perforated loading unit, an unloading unit with hatches in the chamber, a unit for delivery of liquid reagents, and units for aeration, air discharge, heat treatment and mixing in the form of an auger. The loading hole is located in one of the bases of chamber 3. The specific area of holes in the perforated pipe along the chamber axis per its unit of length grows towards the loading unit which is made in the form of a pneumatic conveyor. Auger blades 7 and 8 are combined into two opposite groups converging in the section plane of unloading hatches and are secured to the internal surface of the chamber. The profiled auger blades have projections and are provided with holes. The number of blades does not exceed 12. The spring-loaded air outlet valves are disposed in the chamber base opposite the loading hole. EFFECT: ecologically-clean production process and continuous control, if necessary, of temperature, pH and pressure. 2 cl, 4 dwg, 1 tbl

Description

 The invention relates to feed production and can be used for the preparation of roughage, mainly for farm animals.

A known method of preparation of feed, including loading raw materials into a container, transporting, stacking and mixing it therein, wetting, heat treatment in the presence of chemicals, aeration, fermentation and yeast [1]
A device for the preparation of feed containing a cylindrical chamber with units for supplying liquid reagents, aeration, air discharge, heat treatment and mixing is known.

The unit for mixing, aeration and supply of liquid reagents is a screw with a hollow shaft and holes in the inter-turn space, in which radial hollow tubes of various lengths with an outlet at the end are specially installed [2]
The disadvantages of the prototypes is that the preparation of feed in such a device requires an increased consumption of chemical and biological reagents due to the significant size of the device, and the high quality of the feed is not ensured.

 The aim of the invention is to improve the quality of feed.

 The goal is achieved in a method of preparing roughage, including loading raw materials into a container, transporting and stacking raw materials in it, wetting, introducing a solution of chemical reagents, transporting raw materials with a coolant, aeration, fermentation and yeast, so that the raw materials are loaded in an air stream until filling capacity within 0.65.0.91 of its volume, and transportation and laying of raw materials is carried out by an air stream, the speed of which is maintained within 6.14 m / s, moreover, the raw materials are wetted by flowing water in the air stream when the ratio of the pressure of the supplied water to the pressure of the air stream is within 0.05.0.9, while in the process of fermentation and yeast, the moisture content of the raw material is adjusted to 39.46 and 47.66%, respectively, and the heat treatment is carried out while maintaining the ratio of the temperature of the coolant and the temperature of the raw material within 1 , 7.10.

 This goal is also achieved in a device for the preparation of roughage, including a cylindrical chamber, a loading unit with a loading hole, an unloading unit with hatches installed in the chamber, a unit for supplying liquid reagents made in the form of a perforated pipe located coaxially with the chamber, aeration and air discharge units, heat treatment and mixing in the form of auger blades in that the feed opening is located in one of the bases of the chamber and its area refers to the cross-sectional area of the chamber within 0.05.0.8, the total specific area of the holes of the perforated pipe per unit of its length increases towards the loading unit, which is made in the form of a pneumatic conveyor, and the ratio of the total area of the holes of the perforated pipe to the total surface area is within 0.07.0.15, and the auger blades are formed into two mutually opposite oriented groups having common convergence in the section plane of the discharge hatches, and are fixed on the inner surface of the cylindrical chamber at an angle to the axis of measures relating to the angle between the tangent to the outer surface of the blade and the axis of the chamber within 0.8. 1.5, while the surfaces of the auger blades are made profiled with profiling protrusions, the average height of which relates to the average distance between the protrusions in the range of 0.2-1.1, and holes are made in the auger blades, the ratio of the total area of which to the area of the feed hole is within 1.2.2.8, and the number of auger blades does not exceed 12. The air exhaust unit is located in the opposite base of the feed hole of the chamber and is made in the form of spring-clamped valves installed diametrically against opolozhno circumferentially base in an amount not more than 12, the ratio of the total opening areas of the valves to the total area of the holes of the perforated tube is in the range of 0.85. 1.45.

 A distinctive feature of the loading of raw materials into the tank is that it is carried out in an air stream until the tank is filled within 0.65.0.91 of its volume. Transportation and laying of raw materials inside the chamber is also carried out by an air stream, the speed of which is maintained within 6.14 m / s. Raw materials are wetted by flowing water through a perforated pipe inside the tank in an air stream, and the ratio of the pressures of the supplied water and the air stream is selected within 0.05.0.9. By wetting, the dead weight of the particles of the loaded raw material is increased and maximum filling of the tank volume is ensured.

 In the fermentation process, the moisture content of the raw material is brought up to 39.46%, while the uniformity of wetting ensures the supply of liquid chemicals and aeration using a perforated pipe. During the yeast process, the moisture content of the feed is adjusted to 47.66 and the wetting uniformity is the same as during fermentation.

 Heat treatment is carried out, maintaining the ratio of the temperature of the coolant and the temperature of the processed raw materials within 1.7.10.

 Figure 1 shows the layout of the device; figure 2 device, cross section; figure 3 filling the chamber volume with raw feed; figure 4 is an enlarged image of the profiled surface of the auger blades.

 The feed hole 1 is located in one of the bases 2 of the chamber 3 (Fig. 1), the area of which refers to the cross-sectional area of the chamber 3 (Fig. 2) within 0.05.0.8. The drainage holes 4 of the perforated pipe 5 are made of arbitrary shape, and their total specific area per unit of its length increases towards the loading unit 6, which is made in the form of a pneumatic conveyor.

 The ratio of the total area of the holes 4 of the perforated pipe 5 to the total area of its surface is in the range of 0.07.0.15. The feed moving and unloading unit is made in the form of auger blades 7, 8, formed into two mutually opposite groups having common convergence in the plane 9 of the discharge hatches section 10. The auger blades 7, 8 are fixed on the inner surface 11 of the cylindrical chamber 3 at an angle to the axis chamber 3, relating to the angle between the tangent to the outer surface of the blade 7 and the axis of the chamber 3 within 0.8.1.5. These angles determine the degree of loading of the blades 7, 8 of the screw and characterize their twist.

 The surface 12 of the blades 7, 8 of the screw is made profiled (figure 4) with profiling protrusions 13, the average height of which refers to the average distance between the protrusions within 0.2.1.1. Holes 14 are made in the blades 7, 8 of the screw, the ratio of the total area of which to the area of the feed hole 1 is within 1.2.2.8, and the number of blades 7.8 of the screw does not exceed 12.

 The number of blades over 12 to choose is impractical due to the reduction of the area of the discharge hatches 10 and the need for additional reinforcement of the shell structure of the chamber 3 in the area of the cutouts.

 The air discharge unit 15 is placed in the opposite loading hole 1 of the base 16 of the chamber 3 and is made in the form of spring-clamping valves installed diametrically opposite along the periphery of the base 16 in an amount of not more than 12, while the ratio of the total area of their holes to the total area of the holes of the perforated pipe 5 is in the range of 0.85.1.45.

 Examples of the method and device are summarized in table.

 For convenience, the parameter characterizing the achievement of the goal, it turned out to be appropriate to take the ratio of γ output volumes of the biological mass of feed prepared using the declared objects, and feed prepared in accordance with the prototype.

 As follows from the table, under optimal conditions for the practical implementation of the proposed method and device, the yield of the biological mass of the feed is obtained 1.5-2 times more than the prototypes. The lower and upper boundaries of the parameters reflected in the claims are selected based on the conditions for minimizing the achievement of the goal (lower boundary example 2: γ1.02; upper boundary example 3: γ 1.03). Any exit beyond the upper and lower boundaries makes it impossible to achieve the goal (going beyond the lower border example 4: γ 0.99; going beyond the upper border example 5: γ 0.98).

 In other examples of practical implementation, with the parameter values within the declared limits, the goal is achieved, as follows from the table (examples 6, 7), and any excess of the limit values, regardless of the fact that the values of the other parameters are inside the declared limits, the goal is not achieved (example 8: γ 0.99).

 The proposed method and device provide a closed process, the ecological purity of the preparation of feed, the ability to constantly monitor the process and manage it as necessary (temperature, pH, pressure).

Claims (2)

 1. The method of preparation of roughage, including loading raw materials into a container, transporting and stacking raw materials in it, wetting, introducing a solution of chemical reagents, heat treatment of raw materials with heat carrier, aeration, fermentation and yeast, characterized in that, in order to improve feed quality, loading of raw materials carried out in an air stream until the tank is filled to 0.65 0.91 of its volume, and transportation and laying of raw materials is carried out by an air stream, the speed of which is maintained within 6-14 m / s, and the raw materials are wetted by flowing m of water in the air stream at a ratio of the pressure of the supplied water to the pressure of the air stream in the range of 0.05 - 0.9, while in the process of fermentation and yeast, the moisture content of the raw material is adjusted to 39 46% and 47 66%, respectively, and the heat treatment is carried out while maintaining the temperature ratio coolant to the temperature of the raw materials in the range of 1.7 10.0.  2. A device for the preparation of roughage, including a cylindrical chamber, a loading unit with a loading hole, an unloading unit with hatches installed in the chamber, a liquid reagent supply unit made in the form of a perforated pipe located coaxially with the chamber, aeration units for air exhaust, heat treatment and mixing in the form of auger blades, characterized in that the feed hole is located in one of the base of the chamber and its area refers to the cross-sectional area of the chamber within 0.05 0.8, while the total the specific area of the holes of the perforated pipe per unit of its length increases towards the loading unit, which is made in the form of a pneumatic conveyor, and the ratio of the total area of the holes of the perforated pipe to the total surface area is within 0.07 0.15, and the screw blades are formed in two mutually oppositely oriented groups having common convergence in the sectional plane of the discharge hatches and are fixed on the inner surface of the cylindrical chamber at an angle to the axis of the chamber, relative to the angle between the tangent to the outer surface of the blade and the axis of the chamber within 0.8 1.5, while the surfaces of the auger blades are made profiled with profiling protrusions, the average height of which relates to the average distance between the protrusions within 0.2 1.1, and in the blades holes are made in the screw, the ratio of the total area to the area of the feed opening is in the range 1.2 to 2.8, and the number of screw blades does not exceed 12, and the air discharge unit is placed in the base of the chamber opposite the feed opening and filled in the form of spring-clamping valves installed diametrically opposite on the periphery of the base in an amount of not more than 12, while the ratio of the total area of the valve openings to the total area of the openings of the perforated pipe is in the range of 0.85 to 1.45.

Images