RU2540583C1 - Machine for preparation and fraction separation of forages - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: machine contains a screw drum, device for loading of forage components and device for receptions of ready forages, it has built-in loading and unloading-and-separating device. The devices are designed as bushings, from outer side of which the flange disks with holes are provisioned for their rigid fixing to flange disks mounted and rigidly attached from two sides of the screw drum on its end holes. To the internal surface of bushings at an angle equal to the angle of inclination of helical lines of the main direction of the screw drum to the axis of its rotation and to longitudinal generatrixes of bushings, the curvilinear screw inserts designed as curvilinear plates are attached. In the unloading and separating device the screw inserts are designed punched and protruding above the bushing limits. Inside the drum along the its whole length the integral extension spring is mounted. The drum is manufactured from separate guiding elements of polygonal circular lines of the main direction and two polygonal circular lines of opposite direction. The drum can also be designed from three strips bent alternately in the opposite sides at an angle 140 degrees along incisions, made at an angle 60 degrees to each other and to longitudinal edge of strips with formation of equilateral triangles.

EFFECT: use of the invention will allow for the improvement of forages preparation quality.

22 dwg

Description

The invention relates to a device for the preparation of feed, in particular for mixing coarse, juicy, watery concentrated feed.

Known drum feed mixer (AS USSR No. 614810, class B01F 9/02, 1978) containing a bed, a drive and an inclined rotating housing with multi-helical blades located tangentially to the surface of the drum at an angle of 20-30 degrees.

A disadvantage of the known feed mixer is the insufficient intensity of mixing the feed components, since the multi-way screw blades are directed in one direction, and their guiding elements - screw blades (screw regiments) are located to each other and to the axis of rotation of the drum at the same angles. The intensity of mixing in such a device is low, and the speed of movement of the feed components in several runs directed in the same direction, smooth helical lines is very significant, which leads to the need to ensure high-quality and uniform mixing during fast longitudinal movement of the feed components in the drum.

Closest to the proposed invention is a drum feed mixer (A.S. USSR 1666173, class B01F 9/02, 1991), comprising a drive, a bed and a rotating drum mounted from sections, each of which is made of equal in area equilateral triangles, connected in series with each other to their bases with the formation along the perimeter of the drum equal in number of mutually directed broken helical lines of the main and opposite directions with the same pitch.

A disadvantage of the known feed mixer is the lack of productivity, since the entrance to the screw drum has the shape of an irregular quadrangle asymmetrically to the axis of rotation of the screw drum and has a face at the entrance to the screw drum whose slope is opposite to the direction of movement of the particles of the feed components, therefore, for each revolution of the screw drum there is a return by this anti-directional face from the helical drum of a part of the feed components in the opposite direction to the loading means. As a result, there is no uninterrupted supply, dosage and reliability of the particles of feed components entering the screw drum, which reduces productivity and limits technological capabilities.

The technical solution is the expansion of technological capabilities by ensuring uninterrupted supply, dosage and reliability of the receipt of part of the feed components inside the screw drum, increasing the productivity and separation of finished feed into fractions.

The objective is achieved in that in the machine for preparing feed and separating them into fractions, containing a screw drum mounted on a bed with a rotation drive, means for loading feed components and means for receiving finished feeds, loading and unloading-separating devices mounted in the form of bushings are mounted on the outside of which flange disks are made with holes for hard mounting to flange disks mounted and rigidly attached on both sides of the screw drum on its end holes In this case, curvilinear screw inserts in the form of curvilinear plates rolled not only along the width of a radius equal to half are attached to the inner surface of the bushings at an angle α equal to the angle of inclination of the helical lines of the main direction of the screw drum to the axis of its rotation and to the longitudinal generatrices of the bushings the diameter of the sleeve, but also twisted along the length along the helical lines with a step equal to the pitch of the helical lines of the main direction of the screw drum, and the length of the screw inserts in the loading device is greater than the length of the sleeve two times and they protrude beyond the ends of the bushings on both sides to capture feed components from the feed and uninterrupted, as well as uniformly transfer them into the screw drum, and in the unloading and separating device the screw inserts are perforated and protrude beyond the sleeve, which is also made perforated, only to the side of the screw drum and enter its internal cavity to capture the finished feed and their uninterrupted supply inside the perforated unloading-separating sleeve is adapted I translate, transform the waterfall mode of movement of the finished feed in the perforated sleeve of the discharge-separating device and then transfer it in a quiet laminar mode of movement, followed by the transfer of the finished feed of small fractions through the perforated holes of the screw inserts and the holes of the perforated sleeve of the discharge-separation device into the hopper for receiving small fractions finished feed, mounted on the bed, and the withdrawal of the unloading and separating devices of large fractions of got fodder feed, while inside the screw drum along its entire length is mounted an integral tension spring with a flat section of coils in the form of two cones, the vertices of which are directed towards each other, and the spring is equipped with a device for adjusting the spring pitch, and the screw drum is made of separate guide elements, located along the perimeter of the screw drum with the formation of three broken helical lines of the main direction and two broken helical lines of the opposite direction with a step four times earlier than the pitch of the helical lines of the main direction, the helical drum can also be made of three bands, alternately bent to opposite sides at an angle of 140 degrees along cuts made at an angle of 60 degrees to each other and to the longitudinal edge of the stripes with the formation of equilateral triangles, while the strip bent one to the other along the longitudinal edges at an angle of 70 degrees with the formation of three broken helical lines of the main direction and two broken helical lines of the opposite direction with a step four times smaller pitch of helical lines of the main direction.

The novelty of the invention lies in the fact that due to the design features of the loading device, not only the uninterrupted supply of feed components to the screw drum is ensured, productivity is increased, technological capabilities are expanded, but also their uniform flow inside the screw drum is ensured, which ensures reliable and uninterrupted operation of the machine .

The novelty also lies in the fact that due to the design features of the unloading and separating device, the chaotic movement of feed in the screw drum from the waterfall mode is transferred to a quiet laminar mode of movement in the unloading and separating device and the separation of finished feed into fractions with the subsequent transfer of finished feed of large fractions to a means for unloading, which not only improves the working conditions of the staff, but also simplifies the maintenance of the machine for preparing feed and section their fractionation, expands technological capabilities.

The novelty lies in the fact that screw inserts, rigidly fixed radially on the inner surface of the sleeve, are rolled up in width along a radius equal to half the diameter of the sleeve, and also rolled up in length along a radius equal to the pitch of the helical lines of the main direction, which simplifies manufacturing and extends technological capabilities .

The novelty lies in the fact that the loading device is multi-start, which expands technological capabilities and ensures uninterrupted supply of feed components inside the screw drum.

The novelty also lies in the fact that the inserts are fixed at an angle to the axis of rotation of the screw drum, equal to the angle of inclination of the helical lines of the main direction to the axis of rotation of the screw drum.

The novelty also lies in the fact that a single spring with a flat section of coils in the form of two cones, the vertices of which are directed towards each other, is mounted inside the screw drum, which ensures increased productivity and expanded technological capabilities due to the expansion and compression of the masses of particles of the feed components.

The novelty also lies in the fact that the machine for preparing feed and separating them into fractions is equipped with a device for adjusting the pitch of the coil of the spring, not only when the screw drum stops, but also in the operating mode of the machine.

The novelty also lies in the fact that the screw inserts and the ring of the unloading-separating device are made with perforated holes, which ensures the separation of finished feed into fractions, expanding technological capabilities.

The novelty also lies in the fact that the screw perforated inserts of the unloading and separating device are folded in width along a radius equal to half the diameter of the perforated sleeve, and are simultaneously twisted along the length along the line of the main direction, which ensures uninterrupted, stable movement of the finished feed for unloading and their separation into fraction, expands technological capabilities.

The novelty of the proposal lies in the fact that such a design of the screw drum along the perimeter with helical lines and screw surfaces allows not only to provide longitudinal cascade movement of feed components along the entire length of the screw drum, but also to increase the productivity of feed preparation, expanding technological capabilities.

The novelty is also due to the fact that the cross-sectional shape of the screw drum is an irregular quadrangle, which along the length of the screw drum changes not only the shape and dimensions of the sides of the quadrangle, but also their location relative to the axis of rotation of the screw drum, which violates the stationary motion of the feed components, giving them a waterfall mode movement, and improves productivity.

Figure 1 shows a machine for preparing feed and dividing them into fractions, front view; figure 2 - loading device, front view, in section; figure 3 is a section aa in figure 2; figure 4 - curved screw insert boot device, a visual image; figure 5 - screw drum made of guide elements in the form of equal equilateral triangles, General view; Fig.6 is a scan of the side surface of the screw drum shown in Fig.5; Fig.7 is a cross-section LL in Fig.5; in Fig.8 is a section bb in Fig.5; figure 9 is a cross section GG in figure 5; figure 10 is a cross section DD in figure 5; figure 11 - screw drum made of guide elements in the form of three identical strips, General view; figure 12 is a view A in figure 11; on Fig - one of the stripes with the marking of the fold lines, front view; on Fig - section along EE in Fig.13; on Fig - strip after bending along the straight lines of the marking; in Fig.16 - section II in Fig.15; on Fig - section KK on Fig; on Fig - section PP in Fig; on Fig - section CC in Fig.11; in Fig.20 - unloading and separating device, front view, in section; on Fig - section bB in Fig.20; in Fig.22 - screw perforated insert of the discharge-separating device, a visual image.

The machine for preparing feed and separating them into fractions (figure 1) consists of a frame 1, made in the form of a welded frame. A drive of the main movement is fixed on the bed, consisting of an electric motor 2, a gearbox 3 and four roller bearings 4. The screw drum 5 is equipped with two rims 6, which are supported by roller bearings with flanges 4. A means for loading feed components 7 and a means for mounting are mounted on the bed 1 reception of finished feed 8.

Since the entrance to the screw drum 5 has the shape of an irregular quadrangle (Fig. 7, Fig. 8, Fig. 9, Fig. 10) located asymmetrically to the axis of rotation, and has one face at the entrance to the end hole of the screw drum, the slope of which is opposite to the direction movement of the feed components, then for each revolution of the screw drum, there is a return by this anti-directional face of portions of particles of feed components from the screw drum 5 back to the loading means, i.e. against moving streams of particles of the components of the feed from the means for loading inside the screw drum. As a result, there is no uninterrupted supply, dosage and reliability of the particles of feed components entering the screw drum, which reduces productivity, reliability and technological capabilities. Therefore, after the loading means 7, the loading device 11 is attached to the end face of the screw drum 5 by a flange 9 to the flange 10 of the screw drum (Fig. 1, Fig. 2).

The loading device 11 (FIG. 2, FIG. 3) is made in the form of a sleeve 12, on the outside of which a flange disk 9 with holes for rigidly fastening the sleeve 12 to the flange 10 of the end hole of the screw drum 5 is made on the diameter of the sleeve (FIG. 1). To the inner surface of the sleeve 12 at an angle α equal to the angle of inclination of the helical lines of the main direction of the screw drum 5 (Fig. 5), it is attached to the longitudinal generators of the sleeve 12 of at least three screw inserts 13 in the form of curved rectangular plates (Fig. 2), rolled up in width along the radius equal to half the diameter of the sleeve, and simultaneously twisted along the length along the helical lines with a step equal to the pitch of the helical lines of the main direction of the screw drum 5. These rectangular plates are bent in width and length by known methods. The curved plate 13 (Fig. 4) is fixed rigidly, for example by welding, to the substrate 14 with holes for mounting the plates 13 at an angle α to the inner surface of the sleeve 12, so that the plates 13 protrude beyond the ends of the bushings 12 (Fig. 2).

The machine for preparing feed and separating them into fractions is also equipped with a discharge-separating device 15 attached to the outlet end hole of the screw drum 5 with the help of flanges 16 and 17.

To create inside the screw drum 5 zones of compression and rarefaction of the masses of particles of the components of the feed, to expand the technological capabilities inside the screw drum 5, a tension spring with a flat section of coils in the form of two cones whose vertices are directed towards each other is mounted.

The helical drum 5 of the machine for preparing feed and dividing them into fractions is made of guide elements in the form of equilateral triangles 18 (Fig. 5) and mounted from tetrahedral voids, a scan of such a helical drum 5 is shown in Fig. 6. The tops of the tetrahedra 19-20-21-22-23; 24-25-26-27-28; 29-30-31-32 form distinct three broken helical lines. Such a helical drum 5 is assembled from equilateral triangles 16 in such a way that three broken helical lines of the main direction 19-20-21-22-23 are formed around the perimeter; 24-25-26-27-28; 29-30-31-32 in increments of S and two helical lines in the opposite direction 28-32-22-2-26-30-20-24 and 23-27-31-21-25-25-29-10 in increments of four times smaller, than the pitch of the lines of the main direction, with different angles of the sides.

The screw drum 5 can also (Fig. 14) be made of three strips 33, 34, 35 with the formation along the perimeter of three broken helical lines 36-37-38-39-40; 41-42-43-44-45; 46-47-48-49 of the main direction with step S and two broken helical lines of the opposite direction 45-49-39-43-47-37-41 and 40-44-48-38-42-46-36 in four steps times smaller than the pitch of the helix of the main direction. The screw drum 5 (Fig. 11, Fig. 12) is mounted from the same width strips so that at all break points of the broken helical lines, for example at point 48, two sides converge, for example, 50 and 51 of an equilateral triangle 43-48 -44, two sides 51 and 52 of an equilateral triangle 48-39-49, two sides, for example, 52 and 53 of an equilateral triangle 48-38-39, two sides 53 and 54 of an equilateral triangle 43-47-48. On all the strips (Fig. 13), at an angle of 60 degrees to the longitudinal edges 55 and 56, cuts 57 and 58 are made alternately from opposite sides of the strips, with beveled walls arranged in pairs at an angle to one another by milling, pressure treatment, and the like. The geometry and magnitude of the angles λ, φ, ω, ψ, α, β of the notch bevels (Fig. 14) and their relative position determine the angles of inclination of equilateral triangles 59 to each other. After the fold of the strip (Fig. 15), cuts 60-69; 69-61; 61-70; 70-62; 62-71; 71-83; 63-72; 72-64; 64-73; 73-65; 65-74; 74-66; 66-75; 75-67 are welded, resulting in stiffening ribs. Strips 33, 34, 35 after bending are connected to one another along the longitudinal edges 55, 56 at an angle of 70 degrees (Fig. 19). Such a connection of the three strips 33, 34, 35 becomes possible, since after bending at an angle of 140 degrees along the straight lines 57, 58 (Fig. 13 of Fig. 14 of Fig. 15), faces are formed alternately in opposite directions on the strip in the form of equilateral triangles 59 located on the strip alternately in opposite directions, with the formation along the longitudinal edges of the strips 33, 34, 35 broken lines, for example, 36-37-38-39-40; 41-42-43-44-45; 46-47-48-49 at the break points of which at the vertices, for example, 48 (Fig. 11) converge on two sides, for example, 50-51 of an equilateral triangle, for example, 43-48-44 and two sides, for example, 53- 54 equilateral triangle, for example, 47-38-48.

The connection of the strips 33, 34, 35 can be carried out by known methods, for example by welding.

In Fig.16, Fig.17, Fig.18 shows the angles formed between the faces in the form of equilateral triangles 59 after the folding of the strips.

As experimental and analytical studies show, the optimal rotational speed of the screw drum is 60 rpm, which ensures a waterfall mode of movement of the feed components in the proposed design of the machine for preparing feed and separating them into fractions. However, since the output of the screw drum has the shape of an irregular quadrangle located asymmetrically to the axis of rotation, and there is at least one face opposite the flow of movement to the discharge means 8 at the exit of the screw drum, this not only damages the finished feed and returns them to the screw drum 5, as well as their scattering at the outlet from the end hole of the screw drum, the orderly process of unloading the finished feed is disrupted, the unloading of the machine is not uninterrupted, they reduce I technological capabilities. Therefore, the outlet of the screw drum is provided with a flange 17, to which, using the flange 16, a discharge-separating device 15 is attached (Fig. 20, Fig. 21), made in the form of a perforated sleeve 77 with a flange 16. To the inner surface of the perforated sleeve 77 at an angle α equal to the angle of inclination of the helical lines of the main direction of the screw drum 5 (Fig. 20, Fig. 21) are attached to the longitudinal generators of the perforated sleeve 77 of at least three screw perforated inserts 78 in the form of curved perforated plates 80 (Fig. 22) straight angular in shape, bent in width along the radius equal to half the diameter of the perforated sleeve 77, and simultaneously rolled along the length along the helical lines of the main direction with a step equal to the pitch of the helical lines of the main direction of the screw drum 5. These rectangular perforated plates 80 are bent in width and length known methods. Curved perforated plates 80 are fixed rigidly, for example by welding, to a substrate 79 with holes for attaching screw perforated inserts 78 at an angle α to the inner surface of the sleeve 77, so that the screw perforated inserts 78 extend beyond the perforated sleeve 71 and enter the inner cavity of the screw drum 5.

Inside the screw drum 5, an integral tension spring 81 with a flat section of coils in the form of two cones, the vertices of which are directed towards each other, is mounted. The spring is equipped with a device for adjusting the pitch of the spring 81. Adjusting the spring 81 allows you to select the optimal process conditions for various feed component compositions and create compression and rarefaction zones for the particle mass of the feed components inside the screw drum.

A machine for preparing feed and separating them into fractions is as follows. Feed components are loaded into the drum 5 by means of loading means 7 in a continuous stream. When the drum 5 rotates, the screw inserts 13 from the means for loading capture portions of feed components and due to their rotation together with the sleeve 12 and due to their curvature in width and length, as well as their arrangement at an angle α to the axis of rotation, particles of feed components are transported first on the inner surface of the cylindrical sleeve 12, and then transported, transfer these feed components inside the screw drum 5, thus bypassing a face whose slope is opposite to the direction of movement of the feed components, which Thus, for each revolution of the screw drum, it prevents this portion of particles of feed components from returning from the screw drum 5 back to the loading means 7, i.e. against the moving mass flow of particles of the components of the feed from the means for loading 7 into the screw drum 5. As a result, there is an uninterrupted supply, dosage and reliability of the particles of feed components inside the screw drum, which increases productivity and expands technological capabilities. Further, the feed components move along the entire length of the screw drum 5 along its helical lines of the main direction, while, since the triangles are located along the perimeter of the drum 5 along three broken helical lines of the same direction and two broken helical lines of the opposite direction with different pitch of the helix and at different angles to each other and to the axis of rotation, the feed components are captured and moved by triangles when the drum rotates at different angles to each other, which intensifies the process ss cooking feed. Since the cross-sectional shape of the helical drum along the length of the screw drum is an irregular quadrangle, which along the length of the screw drum changes not only the shape and dimensions of the sides of the quadrangle, but also their location relative to the axis of rotation of the screw drum, the stationary movement of the feed components is violated, which contributes to their intensification cooking. In this case, the transportation of feed components in the screw drum 5 and unloading, separation into fractions is carried out without tilting the screw drum 5 and the entire machine for preparing feed and separating them into fractions, i.e. without complicating the drive of the machine. The presence of broken helical grooves inside the helical drum inside the cavity of the helical drum 5 with a different number of strokes and different steps creates oncoming flows of masses of particles of the components of the feed, informing the waterfall nature of the movement of these masses. This is facilitated by the various angles of the sides of the grooves of the inner cavity of the screw drum 5. Thus, the feed components are given a waterfall mode of movement, which increases productivity and expands technological capabilities.

However, since the output of the screw drum 5, the movement of the finished feed is carried out in a chaotic waterfall mode, which leads not only to disrupt the uninterrupted unloading of the finished feed, the destruction of their granules, the spread of the finished feed when the screw drum 5 is removed from the end hole, which leads to a violation of technology safety and worsening working conditions of staff, then to the end hole at the outlet of the screw drum 5 (figure 1) using the flanges 16 and 17 is fixed unloading and separating device 15, so that Generally, screw perforated inserts 78 extending beyond the end face of the perforated sleeve 77 would enter the internal cavity of the screw drum 5.

Since the perforated screw inserts 78 are mounted at an angle α to the axis of rotation of the screw drum 5, they rotate with their curved perforated plates 80 during rotation to capture finished portions of finished feed, which move along the curved perforated surfaces of the plates 80 in the radial direction smoothly in a quiet laminar mode, with the fine fractions of the finished feed through the perforated holes of the screw inserts 78 and the perforated holes of the sleeve 77 are displayed in the hopper 81 small fractions of the finished feed and large fractions, the size of which is larger than the perforations of the screw insert 78 and sleeve 77, are discharged into the means for receiving finished feed 8, while the quality of the finished product is improved, since the damage to the granules of the finished feed is reduced and their presentation is improved.

Technical and economic benefits from the implementation of the present invention arise due to increased productivity and reliability of the machine for preparing feed and separating them into fractions due to the uninterrupted supply, dosage and reliability of the particles of feed components inside the working body of the machine for preparing feed and separating them into fractions, improving working conditions for staff, separation of finished feed into fractions and reducing the damage to granules of finished feed and improving their marketability species.

Claims (1)

A machine for preparing feed and dividing it into fractions, comprising a screw drum mounted on a bed with a rotational drive, means for loading feed components and means for receiving finished feeds, characterized in that loading and unloading-separating devices mounted in the form of bushings are mounted in the machine on the outside of which flange disks are made with holes for hard mounting to flange disks mounted and rigidly attached on both sides of the screw drum to its end holes holes, while to the inner surface of the bushings at an angle α equal to the angle of inclination of the helical lines of the main direction of the screw drum to the axis of rotation and to the longitudinal generatrices of the bushings, curved screw inserts are attached in the form of curved plates, rolled up not only in width along the radius equal to half the diameter of the sleeve, but also twisted along the length along the helical lines with a step equal to the pitch of the helical lines of the main direction of the screw drum, and the length of the screw inserts in the boot adapted is greater than the length of the bushings and two times they protrude beyond the ends of the bushings on both sides to capture the components of the feed from the loading means and uninterrupted, as well as uniformly transfer them inside the screw drum, and in the unloading-separating device the screw inserts are perforated and protrude beyond the sleeve, which also made perforated, only towards the screw drum and enter its internal cavity to capture the finished feed and uninterrupted supply thereof into the perforated sleeve of the unloading-separating device transfer and conversion, waterfall mode of movement of finished feed in the perforated sleeve of the discharge-separating device into a laminar mode of movement and then transfer in a quiet laminar mode of movement, followed by transfer of finished feed of small fractions through the perforated holes of the screw inserts and holes of the perforated sleeve of the discharge-separating device in a hopper for receiving small fractions of finished feed, mounted on the bed, and the output of the unloading-separating additive outside the sleeve features of large fractions of finished feed, while inside the screw drum along its entire length a single tension spring is mounted with a flat section of coils in the form of two cones, the vertices of which are directed towards each other, and the spring is equipped with a device for adjusting the spring pitch, and the screw drum is made of separate guiding elements located around the perimeter of the screw drum with the formation of three broken helical lines of the main direction and two broken helical lines of the opposite direction with a step four times smaller than the pitch of the helical lines of the main direction, the helical drum can also be made of three strips, bent alternately in opposite directions at an angle of 140 degrees along cuts made at an angle of 60 degrees to each other and to the longitudinal edge of the strips with the formation equilateral triangles, while the stripes are bent to one another along the longitudinal edges at an angle of 70 degrees with the formation of three broken helical lines of the main direction and two broken helical lines of the opposite direction in increments of four times smaller pitch helical lines mainstream.

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