RU2670122C1 - Seed separation machine - Google Patents

Abstract

FIELD: food industry.

SUBSTANCE: invention relates to the food industry and can be used in the canning industry for seed separation. Machine includes a housing, a hollow perforated rotor mounted therein, rotatably mounted, a feeder and a water supply unit. Perforated rotor is made in the form of an installed at an acute angle α relative to the horizontal axis of rotation of a polyhedral perforated prism with flat perforated faces along its perimeter and with flat end perforated walls of polygonal shape, placed at different angles β and ψ To the axis of rotation of the perforated prism and to each other at an angle ϕ. Longest axes of the end perforated walls of the polygonal shape coincide with one another or are rotated along the rotational axis of the perforated rotor relative to each other by an angle ω. Along the entire length of the perforated rotor, a cylindrical spring with a circular section of turns is mounted along its axis of rotation, which is equipped with a device for changing the pitch of the turns, by stretching or compressing it.sion is arranged along container length. Housing is also provided with a seed unloading device and, together with a perforated rotor, is fixed to a frame that is resiliently mounted on the frame.

EFFECT: invention usage allows to enhance seed separation efficiency.

1 cl, 7 dwg

Description

The invention relates to the food industry and can be used in enterprises of the canning industry.

A device for isolating seeds is known (patent No. 2546185, class A23N 4/12, 1992), comprising a cylindrical body provided with a helical guide, mounted for rotation and mounted in it a hollow perforated rotor made of at least one perforated strip bent in straight lines placed at equal distances from each other at equal angles to the longitudinal edges of the perforated strip with the formation of the same perforated parallelograms, located after bending on the perforated the olos alternately in opposite directions from each other, while the perforated strip is folded into cylindrical coils connected to each other along the longitudinal edges with the formation along the perimeter of unidirectional broken helical lines and the same broken helical perforated pockets of a triangular shape on the outer and inner perforated surface of the rotor, equipped receiving screw device, made in the form of a hollow perforated conical shirt with a multiple screw surface, uz water supply, loading and unloading devices.

The disadvantage is the complexity of manufacturing, limited technological capabilities and lack of efficiency of separation of seeds.

Closest to the proposed invention is a plant for the selection of seeds (RF patent No. 2629981, class A23N 4/12, published 05.09.2017, bull. No. 25), comprising a housing and a hollow perforated rotor mounted therein, mounted for rotation, equipped with a raw material loading device, a water supply unit, an unloading device, a perforated rotor around the perimeter made conical, the axis of which is an acute angle with its axis of rotation, and the end cheeks of the perforated rotor are perforated elliptical, p Moreover, the large diameters of the ellipses of the end cheeks are rotated 0 ° -360 ° along the axis of the conical surface relative to each other and are mounted at an acute angle of 10 ° -90 ° not only one to the other, but also at different angles to the axis of rotation of the perforated rotor, while along the entire length of the perforated rotor a spring of cylindrical shape with a flat section of coils and with a direction of coils matching the direction of rotation of the perforated rotor is mounted, equipped with a device for changing the pitch of the coils by stretching or compressing it, and the enclosure is equipped with a seed discharge device and, together with a perforated rotor, is mounted on a frame that is elastically mounted on the bed.

The disadvantage is the limited technological capabilities and lack of effectiveness of the separation of seeds.

The technical solution is to expand technological capabilities and increase the efficiency of the separation of seeds.

The technical solution is achieved by the fact that in the seed separating machine comprising a housing, a hollow perforated rotor mounted therein mounted for rotation, a feed loading device and a feed supply unit, the perforated rotor is configured as a polyhedral mounted at an acute angle α relative to the horizontal rotation axis perforated prism with flat perforated faces along its perimeter and with flat end perforated walls of a polygonal shape placed at different angles and β and ψ to the axis of rotation of the perforated prism and to each other at an angle ϕ, while the longest axes of the end perforated walls of the polygonal shape coincide with each other or are rotated along the axis of rotation of the perforated rotor relative to each other by an angle ω, and, along the entire length a perforated rotor is mounted on its axis of rotation with a cylindrical spring with a round coil section, which is equipped with a device for changing the pitch of the coils by stretching or compressing it, and the casing is equipped with an unloading device for seeds and together with a perforated rotor mounted on a frame, elastically mounted on the frame.

According to the patent literature not found a technical solution similar to the claimed, which allows us to judge the inventive step of the proposed machine for the selection of seeds.

The novelty lies in the fact that the perforated rotor is made in the form of a multifaceted prism mounted obliquely at an acute angle α relative to the horizontal axis of rotation with flat perforated faces along its perimeter and with flat end-shaped perforated walls of a polygonal shape placed at various acute angles β and ψ to the axis of rotation perforated prism, and to each other at an acute angle ϕ, while the large axes of the end perforated walls of the polygonal shape are rotated along the axis of rotation of the perforated roto apart from each other by an acute angle ω, in addition, the drive, the perforated rotor with the loading and unloading pins are mounted on a frame that is mounted by means of rubber cord pneumocylinders on the bed, which creates oscillations due to the imbalance of the masses of the loaded raw materials and the masses of the perforated rotor itself having an axis rotation, which does not coincide with its axis, gives and provides the simultaneous effect of these vibrations on the raw materials in three mutually perpendicular directions, enhances the influence of vibrations of the whole machine I allocation of seeds in the rubber-bellows in the process of extracting the seeds from the fruit, which increases productivity and efficiency, expanding technological capabilities.

The novelty of the invention lies in the fact that such a design of the perforated rotor increases productivity and expands technological capabilities.

The novelty lies in the fact that the combined influence of the rotational motion of the perforated rotor and the raw materials moving inside the particles and the combination of the frame vibrations with the perforated rotors fixed on it gives them a complex spatial movement, which increases productivity and expands technological capabilities.

The novelty lies in the fact that the centers of symmetry of the inner surface of the perforated rotor in each of its cross-sectional elements along its length are displaced relative to the axis of rotation, which violates not only the stationary motion of the particles of raw materials, extends technological capabilities, but also contributes to the creation of eccentricity and excitation of vibrations of the perforated rotor together with frame.

The novelty lies in the fact that as a result of the perforated rotor in the form of a perforated prism mounted obliquely relative to the horizontal axis with perforated end walls placed at different angles not only to the horizontal axis of rotation, but also to each other, the stationary motion of the particles of raw materials that violate complex spatial movement in the vertical plane - along elliptical trajectories, since the perforated rotor is made in the form of an inclined prism around the perimeter, and in horizontal plane - reciprocating, which increases productivity, expands technological capabilities.

The invention is illustrated by drawings, where in FIG. 1 shows a machine for separating seeds, a longitudinal section; in FIG. 2 is a section AA in FIG. one; in FIG. 3 - perforated rotor with a flat end perforated polygonal shape, placed obliquely at an angle to the horizontal axis of rotation of the perforated rotor and to each other; in FIG. 4 is a section BB in FIG. 3; in FIG. 5 is a view A in FIG. 3 perforated ribs in the form of a multifaceted prism with flat end face perforated polygonal walls placed obliquely at an angle to the horizontal axis of rotation of the perforated rotor and to each other, while the large axes of the perforated walls are mounted along the axis of rotation of the perforated rotor without rotation relative to each other (ω = 0); in FIG. 6 is a visual representation of a perforated rotor in the form of a polyhedral prism with flat end-face perforated walls of a polygonal shape, placed obliquely at an angle to the horizontal axis of rotation and to each other, while the longest axes of the end-perforated walls of a polygonal shape are rotated along the axis of rotation at an angle ω> 0 ; FIG. 7 - view B in the form of a diagram - the location of the longest axes of the end perforated walls of a polygonal shape relative to each other.

The seed extraction machine comprises (Fig. 1, Fig. 2) a housing 1 and a hollow perforated rotor 2 mounted therein, mounted for rotation (the drive is not shown in the drawing), equipped with a loading device for raw materials (loading funnel) 3, a water supply unit including a collector 4 and a nozzle 5. The housing 1 is equipped with a seed discharge device 6 and, together with a perforated rotor 2, is mounted on a frame 7, which is elastically mounted on the frame 8 using four elastic elements 9. The seed separation unit contains (Fig. 1, 2) also un a loading tray 10 for receiving the destroyed fruit and an unloading tray 11 for receiving seeds, as well as a tray 12 for collecting fibers and water. Unloading device of seeds 6 includes a perforated bottom 13 of the housing 1. The housing 1 itself consists of directly the housing 1 and the cover 14, rigidly fastened to each other. On the unloading side of the seeds in the housing 1 above the perforated bottom 13 of the housing 1 there is a rectangular hole 15 for withdrawing seeds outside the housing 1 of the installation for seed separation. The perforated rotor 2 is mounted for rotation on the supports 16 and 17, which are mounted on the frame 7.

The perforated rotor 2 is made in the form of a polyhedral perforated prism mounted at an acute angle α relative to the horizontal axis of rotation with flat perforated faces 25, 26, 27, 28, 29, 30 (Fig. 4) along its perimeter and with flat end perforated walls 18 and 19 polygonal shape, placed at different angles β and ψ to the axis of rotation of the perforated prism and to each other at an angle ϕ, while the longest axis of the end perforated walls 18, 19 of the polygonal shape are rotated along the axis of rotation of the perforated roto and 2 relative to each other at an angle ω, and, along the entire length of the perforated rotor 2, a cylindrical spring 24 with a round coil section is mounted along its axis of rotation, which is equipped with a device for changing the pitch of the coils by stretching or compressing it, and the housing 1 is equipped with a discharge device seed 6 and together with the perforated rotor 2 is mounted on the frame 7, elastically mounted on the frame 8. The end perforated walls 18 and 19 of the perforated rotor 2 are made polygonal (Fig. 4), while the longest axes of the end perforated walls of the polygonal shape can coincide or are rotated along the rotation axis of the perforated rotor 2 relative to each other by an angle ω. The end perforated walls 18 and 19 are polygonal in shape, placed at different angles β and ψ to the axis of rotation of the perforated prism and to each other at an angle ϕ, i.e. at an acute angle of 10 ° -90 ° to one another. The perforated rotor 2 is equipped with bushings 20 and 21 with support rings 22 and 23 mounted for rotation on the supports 16 and 17. To provide additional longitudinal movement of the particles of the feed stream inside the perforated rotor 2, a coil spring 24 with a round coil section, with the direction of the coils is mounted, coinciding with the direction of rotation of the perforated rotor 2. The spring 24 is equipped with a device for changing the pitch of the turns of the spring 24 by stretching or compression (not shown). The adjustment of the pitch of the turns of the spring 24 can be carried out in the process of seed allocation. Such a design of the perforated rotor 2 creates an imbalance in the rotating perforated rotor 2, which gives it and the casing 1 low-frequency oscillations, which not only intensify the process of crushing raw materials and seed allocation, but also ensure the reliability of the movement of seeds along the bottom 13 of the casing 1 and their output beyond installation.

The perforated rotor 2 (Fig. 1, Fig. 2, Fig. 3, Fig. 4, Fig. 5) is made in the form _of rotation of a multifaceted prism mounted obliquely at an angle α relative to the horizontal axis 0 ₁ -0 ₁ with flat perforated faces 25, 26 , 27, 28, 29, 30 along its perimeter and with flat end perforated walls of a polygonal shape 19 with the longest axis i ₁ and 18 with the longest axis i ₂ placed at different angles β and ψ to the axis of rotation of the prism and to each other at an angle φ, wherein the longest axis of i ₁ and i ₂ the perforated end wall polygonal pho we 19 and 18 coincide (ω = 0) with each other (FIG. 2, FIG. 4). The perforated rotor with loading and unloading pins 20 and 21, the drive (not shown in the drawing) is mounted on a frame 7, which is mounted elastically with four pneumocylinders 9 on a frame 8.

Perforated rotor 2 can be made (Fig. 6 and Fig. 7) with end perforated walls 19 and 18, the longest axis of which i ₁ and i ₂ can be rotated relative to each other by an acute angle ω> 0 (Fig. 6 and Fig. 7).

The longest axes i ₁ -i ₁ and i ₂ -i _{2 of the} end perforated walls 19 and 18 (i ₁ -i ₁ ≡i ₂ ¹ -i ₂ ¹ ) (Fig. 6) are rotated along the axis of rotation of the perforated rotor 2 relative to each other angle ω.

Thus, the longest axes i ₁ -i ₁ and i ₂ -i _{2 of the} end perforated walls of the polygonal shape of the perforated rotor 2 (Fig. 3) are rotated along the rotation axis 0 ₁ -0 _{1 of the} perforated rotor 2 relative to each other by an angle ω. In FIG. 7 shows the location of the longest axis of the end i ₁ -i _{1 of the} end wall 19 of the perforated rotor 2 at the loading sleeve 20 relative to the longest axis i ₂ ¹ -i ₂ ^{1 of the} end wall 6 of the perforated rotor 2 at the unloading sleeve 21, which are rotated relative to each other by angle ω, with i ₁ -i ₁ ≡i ₂ ¹ -i ₂ ¹ .

Machine for the selection of seeds works as follows.

Particles of raw materials - crushed melons, for example pumpkin, enter through a loading funnel 3 and a sleeve 20 into a rotating perforated rotor 2, where they move along various elliptical trajectories, the dimensions of which vary along the length of the perforated rotor 2 in each cross section, while the particles of raw materials make complex spatial motion in the vertical plane — along elliptical trajectories, since the perforated rotor 2 is oblique, and in the horizontal plane — reciprocating. As a result, the flow of moving particles of raw materials is not stationary, and the size and location of the active movement of flows of raw materials noticeably change during one revolution of the perforated rotor 2. Therefore, as a result of a disorder in the process of movement of particles of flows of raw materials, their movement becomes more active, the immobility zone is eliminated, and it increases the energy intensity of the collisions of the particles of raw materials with each other and with the walls of the perforated rotor 2, as well as with the end perforated walls 18 and 19, which ensures the cleaning of their perforated bathroom surfaces and improves the efficiency of destruction of fruit and seed separation. The process of non-stationary motion of the particles of raw materials is aggravated by the location of the end perforated walls 18 and 19 of a polygonal shape, which significantly changes the direction of movement of the particles of raw materials along the axis of rotation of the perforated rotor 2 and creates zones of different pressure of the end perforated walls 18 and 19 on the particles of raw materials and intensifies the process of their destruction and separation of seeds. Therefore, the particles of raw materials are able under the influence of the geometric slope of the perforated rotor 2 and the pressure difference of the end perforated walls of the elliptical shape 18 and 19 located to each other and to the axis of rotation of the perforated rotor 2, not only move along complex paths, but also move in the axial direction, creating turbulent flows of particles of raw materials. As a result of such an intensification of the flow movement, the raw material particles are destroyed, the seeds, together with water and fibers, are removed outside the perforated surface of the perforated rotor 2, flow down the walls of the housing 1 and fall on the perforated bottom 13 of the housing 1. Water and fruit fibers through the holes of the perforated bottom 13 are discharged into a tray 12 for collecting fibers and water, and the seeds through the hole 15 and the unloading device 6 are displayed outside the housing 1 in the unloading tray 11 for receiving seeds. Destroyed fruits through the sleeve 21 and the spring 24 are displayed outside the housing 1 and the perforated rotor 2 in the unloading tray 10 for receiving the destroyed fruits.

The movement of particles of raw materials that rise up and fall down is continuous. Since the internal perforated walls of the perforated rotor 2 are located at an angle not only to each other, but also to its axis of rotation, in each portion of the feed, each feed particle moves along its direction vector towards the discharge side, which greatly intensifies the process of fruit destruction and seed extraction, expanding technological capabilities. The process of fruit destruction and seed extraction is also intensified by a spring 24 mounted inside a perforated rotor 2 with a round cross-section and a direction of turns coinciding with the direction of rotation of the perforated rotor 2, which provides additional longitudinal movement of raw material particles inside the perforated rotor 2. Spring 24 is equipped with a device for changing pitch turns by stretching or compression (not shown). The adjustment of the pitch of the turns of the spring 24 can also be carried out during the operation of the plant for seed separation. Depending on the characteristics of the raw materials, the time required for the complete separation of seeds, a spring pitch is set that meets the optimal conditions for the technological process of seed separation. In the desired position, the spring 24 is fixed with known devices (not shown). At the same time, the design of the perforated rotor 2 creates an imbalance in the rotating perforated rotor 2, which gives it and the casing 1 low-frequency oscillations, which not only intensify the process of crushing raw materials and seed separation, but also ensure the reliability of the movement of seeds along the bottom 13 of the casing 1 and their output outside of the installation.

Technical and economic benefits are provided due to the intensification of the process of seed separation, due to the violation of the stationary flow of the particles of raw materials inside the perforated rotor and the expansion of technological capabilities. Technical and economic advantages are also ensured by creating unbalance in a rotating perforated rotor, which gives it and the casing low-frequency oscillations, which not only intensify the process of crushing raw materials and seed separation, but also ensure the reliability of the movement of seeds along the bottom of the casing and their removal outside the installation.

Claims (1)

A seed extraction machine comprising a housing, a hollow perforated rotor mounted therein, rotatably mounted, a raw material loading device and a water supply unit, characterized in that the perforated rotor is made in the form of a multifaceted perforated prism installed at an acute angle α relative to the horizontal axis of rotation with flat perforated faces along its perimeter and with flat end perforated walls of a polygonal shape placed at different angles β and ψ to the axis of rotation of the perforated prism and to each other at an angle ϕ, while the longest axes of the end perforated walls of the polygonal shape coincide with each other or are rotated along the axis of rotation of the perforated rotor relative to each other by an angle ω, in addition, along the entire length of the perforated rotor along its axis of rotation a cylindrical spring with a round coil section is mounted, which is equipped with a device for changing the pitch of the coils by stretching or compressing it, and the casing is equipped with a seed unloading device and together with a perforator bathrooms rotor is mounted on the frame, is resiliently mounted on the frame.

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