RU2491809C1 - Combined harvester - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention relates to agricultural machinery industry. The combined harvester comprises a header, a crop feed elevator, a threshing and separation unit with the receiving helical device, and a blower. The threshing and separation unit is made in the form of outer, middle and inner helical drums coaxially mounted with a clearance. The outer drum is made along the perimetre of three or more variable-area stripes folded in the vertical plane and interconnected in series. The middle drum is mounted of sections made of an even number of equilateral triangles interconnected with their lateral sides. The sections are interconnected by free third sides of the triangles to form the helical drum. Along the perimetre of the helical drum the directed towards each other broken right and left helices with internal helical grooves are located. The inner drum is mounted of at least one bent perforated stripe folded into cylindrical coils to form perforated pockets of polygonal shape.

EFFECT: combined harvester has high performance due to regular lengthwise movement of the stalked mass in the inner drum of the threshing and separation unit.

27 dwg

Description

The invention relates to the field of agricultural engineering, in particular to combine harvesters.

Known is a direct-flow combine harvester (RF patent No. 2391808, CL A01D 41/00, A01F 7/06, A01F 12/18, publ. 06/20/2010 Bul. No. 17), including a header, an inclined chamber, a blower and a threshing machine a separation apparatus, the threshing and separation apparatus of which is made in the form of screw drums coaxially installed with a gap, for example three, external, middle and internal, each of which is made of separate flat elements with the formation of a multi-helical surface, while the outer drum is made around the perimeter of three or more perforated stripes folded in a vertical plane and successively connected to each other, of a variable width of a convex curvilinear shape, folded in a vertical plane to the longitudinal direction, curved along helical lines in the transverse direction and bent along notches, with beveled walls in the transverse-longitudinal direction, arranged in pairs at an angle to one another on both sides of the strips with the formation along the perimeter of the drum broken helical lines directed towards each other and broken screw surface with the same variable pitch along the length of the drum, and the middle drum is assembled from sections made of several equilateral triangles in the amount of an even multiple, for example twelve, interconnected by two side sides, while the sections are connected to each other by free third sides of the triangles with the formation a helical drum, along the perimeter of which broken right and left helical lines directed towards each other are provided with internal helical grooves and directed towards each other with the same constant step along the length of the drum, and the inner drum is made of at least three perforated rectangular strips of the same width but the entire length of the strips, rolled in a vertical plane in the longitudinal direction relative to the axis of symmetry of the strip and curved in a helix in the transverse direction on a cylindrical mandrel, while the receiving screw device is made of at least three perforated strips of trapezoidal shape with different sizes in the width, with increasing along the length of the receiving part, twisted in the vertical plane in the longitudinal direction relative to the axis of symmetry of the strip and curved along the helical line in the transverse direction on the conical mandrel, the end holes of the screw drums on the loading side between the inner and middle drums, and between the middle and outer drums are covered by a shell with the possibility of supplying them with an air stream from the blower, while the end hole of the inner drum from the loading side is open o, and all the holes are visible by the three reels and unloading device through the feed screw and the inner cavity of the inner drum screw axis extends, mounted in two bearings supported by two beams combine harvester housing.

The disadvantage of this combine is the limited technological capabilities, the complexity of manufacturing.

Closest to the proposed invention is a combine harvester (RF patent No. 2435358, class A01D 41/00, A01F 7/06, A01F 12/18, publ. 10.12.2011 Bull. No. 34), including the header, tilt chamber, blower and threshing and separation apparatus made in the form of screw drums coaxially installed with a gap, for example three, external, middle and internal, each of which is made of separate flat elements with the formation of a multi-helical surface, while the outer drum is made around the perimeter of three or more rolled into ve the vertical plane and perforated strips connected in series, of a variable width of a convex curvilinear shape, rolled in a vertical plane in the longitudinal direction, curved along helical lines in the transverse direction and bent along notches, with beveled walls in the transverse-longitudinal direction, arranged in pairs at an angle of one to to the other on both sides of the strips with the formation but along the perimeter of the drum, broken helical lines directed towards each other and broken helical surfaces with the same with a variable step along the length of the drum, and the middle drum is mounted from sections made of several equilateral triangles in the number of multiples of an even number, for example twelve, connected to each other by two sides, while the sections are connected to each other by free third parties of the triangles with the formation of a screw drum, but along the perimeter of which are broken right and left helical lines directed towards each other, equipped with internal helical grooves directed towards each other with the same constant step along the length of the drum, and the receiving screw device is made of at least three perforated strips of trapezoidal shape with different sizes in width, increasing them along the length of the receiving part, twisted in a vertical plane in the longitudinal direction relative to the axis of symmetry of the strip and bent along the helix in the transverse direction on the conical mandrel and the end holes of the screw drums on the loading side between the inner and middle drums, as well as between the bottom and outer drums are covered by a shell with the possibility of supplying them with an air flow from the blower, while the end hole of the inner drum from the loading side is open, and the openings of all three drums from the discharge side are open and the axis passes through the receiving screw device and the inner cavity of the internal screw drum mounted on two supports supported by two beams of the combine body, and the inner drum is made in the form of a perforated surface with screw grooves inside and and the inner drum at an angle of 5º-30º to the axis of rotation of the drum in the form of pockets of a curved shape with centers of curvature of the pockets, alternately located outside and inside the cross section of the inner drum, mounted from one, rolled into cylindrical coils, connected to each other along longitudinal edges, perforated strips of the same width, bent in a wave-like fashion along bending lines placed at an angle to all longitudinal edges with the formation along the outer and inner surfaces directed to one side at an angle of 5º-30º to the axis of rotation of the inner drum of the helical surfaces in the form of pockets of curved shape on the outer and inner surfaces, which along the perimeter of the inner drum can be different not only in shape but also in size, while the distance between the fold lines is equal to the sum of the lengths of the perimeters of the geometric shapes of the pockets of the inner and outer surfaces.

The disadvantage of this combine is the limited technological capabilities, as well as the limited possibilities for the longitudinal movement of the stalk mass in the inner drum with a wavy undulating inner perforated surface.

The technical solution is the expansion of technological capabilities, ensuring uninterrupted movement of the movement of the stalk mass in the inner drum.

The technical solution is achieved by the fact that in the combine harvester, including a header, an inclined chamber, a blower and a threshing and separation apparatus equipped with a receiving screw device, made in the form of screw drums coaxially installed with a gap, for example three, external, middle and internal, while the outer drum made with the formation of a multi-helical surface along the perimeter of three or more vertically rolled up and sequentially interconnected bands of variable width curvilinear curved in the vertical plane in the longitudinal direction, curved along helical lines in the transverse direction and bent but notched, with beveled walls in the transverse-longitudinal direction, arranged in pairs at an angle to one another on both sides of the strips with the formation along the perimeter of the drum directed towards each other broken lines and broken helical surfaces with the same variable pitch along the length of the drum, and the middle drum is mounted from sections with the formation of mnogozah one helical surface made of several equilateral perforated triangles in an even multiple of an even number, for example twelve, interconnected by two lateral sides, the sections being connected to each other by the free third sides of the triangles with the formation of a helical drum, but the perimeter of which are directed towards each other broken right and left helix lines equipped with internal helical grooves directed towards each other with the same constant m step but the length of the middle drum, while the end holes of the screw drums on the loading side between the inner and middle drums, and also between the middle and outer drums are covered by a shell with the possibility of supplying air flow from the blower to them, while the end hole of the inner drum is on the loading side open, and also open the holes of all three drums from the unloading side and an axis mounted on two passes through the receiving screw device and the internal cavity of the internal screw drum the supports supported by two beams of the combine body, the inner drum is mounted from at least one rolled into cylindrical coils connected to each other along the longitudinal edges of the perforated strip bent along the bending lines placed at an angle to its longitudinal edges, with the formation of the outer and inner surfaces directed to one side of helical lines and helical surfaces in the form of perforated pockets of a polygonal shape, the distance between the fold lines is equal to the length of each polygon element , The perforated pockets along the inner surface may be different from the shape and dimensions of perforated pockets on the outer surface and the perimeter of the drum may be different not only in sections, but also in shape.

According to the patent literature not found a technical solution similar to the claimed, which allows to judge the inventive step of the proposed combine harvester.

The novelty lies in the fact that such a structural design of the inner drum allows for reliable axial movement of the stalk mass from loading to unloading with a horizontal axis of rotation of the drum, which provides better grip of the stalk mass with polygonal pockets and its movement along the longitudinal axis of rotation of the inner perforated drum and expands technological capabilities.

The novelty lies in the fact that due to the broken polygonal internal perforated screw pockets, the vectors of the speed of motion of the particles of the stalk mass change during transportation from loading to unloading, which contributes to the intensification and extends technological capabilities.

The novelty of the proposal also lies in the fact that screw perforated surfaces are formed inside the drum in the form of broken perforated pockets of a polygonal shape, which intensifies the process of separating grain from the stalk mass and expands technological capabilities.

The novelty also lies in the fact that helical surfaces and helical grooves of a polygonal shape swirl the flow of stalk mass, which intensifies the process of separation of grain from the stalk mass.

The novelty also lies in the fact that the pockets around the perimeter of the drum can be different not only in shape but also in size, which expands the technological capabilities

The novelty also lies in the fact that for the same drum diameters in the proposed drum design, the path length of the particles of materials in comparison with the known drum designs is much larger along the perimeter, which makes it possible to reduce the dimensions of the drum, both in length and in diameter , and also contributes to the intensification of the process of separating grains from the stalk mass and expands technological capabilities

The novelty of the proposal also lies in the fact that along the entire perimeter of the perforated screening surface of the drum, the passage section varies not only in shape but also in area, which provides alternate compression and expansion of the stalk mass in each section of the drum, its self-cleaning, which means an increase in productivity, efficiency , reducing the size and expanding technological capabilities.

The novelty of the proposal also lies in the fact that with the same diameters of the inner drum in the proposed design, the contact area of the walls of the drum with a stalk mass increases compared to the known design of the inner drum, which expands the technological capabilities.

The novelty of the proposal lies in the fact that due to the design features of the inner drums, an increase in the frequency and energy intensity of the interaction between the stalk mass and spikelets is ensured not only with each other, but also with the polygonal shape of the perforated walls of the inner screw drums, which expands the technological capabilities of the combine.

The novelty of the proposal also lies in the fact that with the same diameters of the inner drum in the proposed design, the contact area of the walls of the drum with the stalk mass increases compared with the known design of the inner drum, which expands the technological capabilities.

The novelty also lies in the fact that with the same diameters of the inner drum in the proposed design of the inner drum, the cross-sectional area of the inner perforated drum is larger, which expands the technological capabilities and makes it possible to reduce the dimensions of the inner drum, and hence the combine as a whole, both in length , and the diameter of the drums, and therefore the width and height of the combine.

Figure 1 shows a combine harvester, side view; figure 2 - threshing and separation apparatus, side view; in Fig 3 - threshing and separation apparatus, section aa in Fig.2; figure 4 - outer drum convex shape of the threshing and separation apparatus, side view; figure 5 - the outer drum of a convex shape of a threshing and separation apparatus, view A in figure 4; in Fig.6 - one of the perforated strips of variable width from which the outer convex drum of the threshing-separation apparatus is made; Fig.7 section BB in Fig.6; on Fig - perforated strip of variable width (Fig.6) after twisting in a vertical plane in the longitudinal direction relative to its own axis of symmetry of the perforated strip; Fig.9 - perforated strip of variable width (Fig.6) after bending along helical lines on a barrel-shaped mandrel; figure 10 is an average multisection perforated drum threshing and separation apparatus, side view; figure 11 is a section bb in figure 10; on Fig - internal perforated screw drum threshing and separation apparatus assembly with a receiving screw device, side view; on Fig - internal perforated screw drum assembly with a flange, side view; on Fig - view B in Fig; on Fig - internal screw perforated drum, General view; Fig. 16 is a section G-G in Fig. 15; on Fig - a perforated strip with marked lines of fold in the form of straight lines for perforated pockets of the polygonal shape of the drum of Fig.15; on Fig - perforated strip, bent but in straight lines with the formation of perforated pockets of a polygonal shape; in Fig.19 is a perspective view of a perforated strip (Fig.18), rolled into a cylindrical coil; in Fig.20 - receiving screw device, complete, visual image; on Fig - removable cover receiving screw device, a visual image; on Fig - receiving screw device, side view; in Fig.23 is a view of D in Fig.22; on Fig - section DD in Fig; on Fig - one of the perforated strips of a trapezoidal shape, from which the receiving screw device of the threshing and separation apparatus is mounted after twisting in a vertical plane in the longitudinal direction relative to the axis of symmetry of the strip; on Fig - perforated strip of a trapezoidal shape after bending in the transverse direction along helical lines on a conical mandrel; on Fig - section EE in Fig.26;

Combine harvester 1 (figure 1) contains a housing 2 having vertical side walls 3, supported by two driving wheels 4 mounted in front and having a relatively large diameter, and two rear 5 steered wheels. In addition, the harvester 1 contains a platform with a driver’s cabin 6, a header 7, an inclined chamber 8, a grain conveyor 9, and an engine (not shown) of the housing 2. In the housing 2, a threshing and separation apparatus 10 is mounted rotatably around its longitudinal axis. Combine 1 also includes a blower 11, auger 12 after the third cleaning of grain, leading to the conveyor of grain 9.

The threshing and separation apparatus 10 (Fig. 1, Fig. 2, Fig. 3) is equipped with two circular shells 13, is mounted horizontally along the longitudinal axis of the combine 1 using known means and can be rotated by a drive 14 from the engine 15.

The threshing and separation apparatus 10 (Fig. 1, Fig. 2, Fig. 3) is made in the form of screw drums coaxially installed with a clearance, for example, three, an external convex screw drum 16 with an average multisection screw 17 and an internal screw coaxially and rigidly mounted in it 18 perforated drums by known means in the form of threaded rods 19. The inner screw perforated drum 18 on the loading side is provided with a receiving screw device 20, which is rigidly fastened to the internal screw drum 18. Through the morning cavity of the screw drum 18 and the screw device 20 passes the axis 21 (Fig. 1) mounted on two supports 22 and 23 supported by transverse beams (not shown in the drawings) on the housing 2 of the combine 1. End holes of the drums 16, 17, 18 (Fig. .1, figure 2, figure 3) from the unloading side are open for the output of straw and other waste. The end hole of the receiving screw device 20 from the loading side is open for loading with an inclined chamber 8 of a grain pile mowed during the movement of the combine 1 and equipped with a conical removable cover 24. The end holes on the loading side of the middle drum 17 and the outer drum 16 are closed (Fig. 1) by a circular shell 25 with the possibility of feeding into the cavity "A" between the middle drum 17 and the inner drum 18 and into the cavity "B" between the middle drum 17 and the outer drum 16 of the air flow from the blower 11 into the cavity "A" and the cavity "B "to separate the chaff and litter from the grain and remove them outside the screw threshing and separation apparatus 10. The end openings of all three drums 16, 17, 18 from the unloading side are open to remove straw, floor and fine litter.

The outer convex drum 16 (FIG. 4, FIG. 5) is made of variable width strips 26, 27, 28, 29, 30, 31 (FIG. 6) with notches (FIG. 7) twisted not only in a vertical plane in the longitudinal direction relative to the axis of symmetry of the strip (Fig. 8), but also in the transverse direction on the barrel-shaped mandrel along helical lines (Fig. 9). Since the strips 26, 27, 28, 29, 30, 31 have a variable width (Fig. 6), the outer drum 16 (Fig. 4, Fig. 5) has a variable longitudinal section and a variable passage cross section along the length of the drum 16. In addition, the strips 26, 27, 28, 29, 30, 31 are ribbed in the longitudinal-transverse direction, forming along the perimeter of the screw drum 16, (Fig. 4, Fig. 5) alternating triangular faces, for example, faces 32, 33, 34, 35, 36, 37, 38, 39, etc. for a strip, for example, 28. Moreover, every two adjacent faces, for example 32 and 33, 33 and 34, etc. are located at an obtuse angle to one another on the outer and inner sides of the perforated strips 26, 27, 28, 29, 30, 31, intersect with each other with the formation of helical lines of the main direction in increments of S ₁ , for example, 40-41-42-43-44 -45-46 on the outer surface and the helical grooves on the inner surface of the outer screw drum 16. Pa figure 4 and figure 5 one of the helical lines with a step S _{1 of the} main direction 40-41-42-43-44-45-46 shown thickened line. On the outer surface of the drum 16, helical grooves and helical lines of the opposite direction are also formed in increments of S ₂ , for example, 47-48-49-43-50-51-52, which are shown in FIG. 4, FIG. 5 by a thickened line. The helical lines on the outer surface of the drum 16 have the same position designations with their corresponding grooves on the inner surface, and the helical grooves and helical lines of the drum 16 can have a different number of starts and different helix steps.

On strips 26, 27, 28, 29, 30, 31, before folding, cuts 53, 54 are made with beveled walls arranged in pairs at an angle to one another, as, for example, in FIG. 6, FIG. 7 by milling a pressure treatment and t .P. The geometry and magnitude of the angles Δ, ξ, σ, τ, ν, χ of the bevels of the notches and their mutual arrangement corresponds to the number of approaches and the values of the steps of helical lines of the opposite direction. The incisions 53, 54 create (Fig.6, Fig.7) alternately from opposite sides of each strip 26, 27, 28, 29, 30, 31. Then, relative to the longitudinal axis, each of the strips 26, 27, 28, 29, 30, 31 twist in a vertical plane relative to the longitudinal axis of the strip. On Fig shows one of the strips twisted in a vertical plane along its longitudinal axis, with lateral edges 55 and 56 located along helical lines along the longitudinal axis. A strip, for example 26, previously twisted in a vertical plane relative to the longitudinal axis, is placed on a barrel-shaped mandrel 57 ( 9) and bend so that the side edges 55 and 56 are placed along helical lines and in the transverse direction. After bending in the cross section on the barrel-shaped mandrel 57, each strip is rotated relative to the longitudinal axis of the drum 16 so that its edges also form helical lines in the transverse direction of the strip with the same pitch for all strips. After that, the strip 26 is deformed and removed from the mandrel 57. The remaining strips, for example, 27, 28, 29, 30, 31, are processed in a similar way. Then, all the deformed strips 26, 27, 28, 29, 30, 31 are combined and connected by known methods , for example, by welding. Perforated holes are made around the entire circular perimeter of the largest diameter of the convex drum 16 of width L equal to three diameters of the screw 12, the diameter of which ensures the passage of clean seeds of grain crops and for their removal outside the screw threshing and separation apparatus 10 and feeding it into the screw 12. Since the strip , of which the drum 16 is mounted, are folded not only in the longitudinal but also in the transverse direction, then along the perimeter of the drum are formed various in step, directed towards each other, screw inner surfaces Surfaces and their joints are screw grooves. The formation of a complex inner surface in the form of a combination of two curved surfaces, at each point of which multidirectional motion components occur, increases the intensity of the movement of grains and fine litter in the area between the middle drum 17 and the outer barrel-shaped drum 16, which allows the air flow from the blower 11 to improve the quality of separation from pure grains of fine litter and expands the technological capabilities of the combine.

The middle multi-sectional perforated drum 17 is assembled from sections 58 (FIG. 10, FIG. 11), each of which is formed of twenty-four equilateral perforated triangles 59 (shown in FIG. 10 by a double line) of the same size, interconnected two lateral sides 60 and 61, while sections 58 are interconnected by third, free sides 62 of perforated triangles 59. After connecting sections 58 to each other, an average multi-section perforated screw bar is created Aban 17 (figure 10, figure 11) with the formation along the perimeter of the screw drum 17 twelve right and twelve left broken helical lines directed towards each other. One of the twelve right-hand broken helical lines with an S ₃ step is shown in FIG. 10 with a thickened line 63-64-65-66-67-68-59-70-71-72-73-74. One of the twelve left broken helical lines with a step of S _{4 is} shown in FIG. 10 with a thickened line 75-76-77-78-79-80-68-81-82-83-84-85. The shape and dimensions of the cross section of the screw perforated drum 17 (11) repeatedly change along the length of the drum. The diameter of the holes of the perforated middle drum 17 provides the passage of seeds of grain crops. When the screw drum 17 rotates, flat elements - equilateral triangles mounted around the perimeter of the screw drum 17 are differently inclined to the axis of rotation of the screw drum 17 and to each other, working as buckets (shelves) capture different mixes of grain, spikelets and litter, lift them in the direction the rotation of the screw drum 17 is slightly higher than the angle of repose, and then these portions of the mixture of grain, floor and litter are directed in the directions perpendicular to these shelves not only at some angle to the axis of rotation of the drum 17, n about and to other flows of similar portions of the grain of the strip and litter at different angles and with different speeds. The length of their movement path depends on the diameter of the screw drum 17, on the angles of the flat elements to each other and on the axis of rotation of the drum 17. The frequency of movement and collisions of grains, spikelets of litter is determined not only by the frequency of rotation of the screw drum 17, but also by the number of flat elements perimeter. Therefore, in the screw drum 17 provides an increase in the frequency response of the movement of grain, spikelets and litter dozens of times, expanding the technological capabilities of separating them from each other. Since the shape and dimensions of the cross section having the shape of a polygon change many times along the length of the screw drum 17 from loading to unloading, multiple periodic compression of moving masses of grain, spikelets, and litter is ensured, which increases the intensity of mixing, the energy intensity of the collisions, and extends technological capabilities.

The inner screw perforated drum 18 (Fig.12) is equipped with a receiving device 20, rigidly fastened to the screw drum 18 with flanges 86 and 87.

The inner screw perforated drum 18 (Fig.13, Fig.14) is rigidly fastened to the flange 86.

The inner screw perforated drum 18 (Fig. 15, Fig. 16) is made of one perforated strip 88, rolled into cylindrical coils (Fig. 15), connected along the longitudinal edges 89 (shown in Fig. 15 by a dashed line) by known methods, for example, by welding, with the formation of helical lines along the outer and inner surfaces (in Fig. 15, one of the helical lines is shown by a thickened line 90-91-92-93-94-95-96-97-98-99-100-101 and helical surfaces (Fig.16) polygonal in the form of perforated pockets of the outer surface of a rectangular shape 10 2, 103, 104, 105, 106, 107 and rectangular perforated pockets of the inner surface 108, 109, 110, 111, 112, 113.

The perforated strip 88 (FIG. 17, FIG. 18) is bent along the bend lines 114 at equal angles α to the longitudinal edges 89 of the strip 88, placed at distances equal to the length of the polygon elements of the pockets, for example, for pocket 107 at distances L ₁ L ₂ L ₃ . The strip 88 after bending along straight lines (Fig. 18, Fig. 19) is folded into cylindrical coils (Fig. 19) connected to each other along the longitudinal edges 89 by known methods, for example, by welding into a perforated drum 18.

The diameter of the holes of the perforated inner screw drum 18 provides the passage of not only grain, but also spikelets of grain crops in length.

The receiving screw device 20 (Fig. 20) is made in the form of a truncated screw cone and forms a funnel-shaped screw inlet, with the help of which the stalk mass, fed back from the inclined chamber 8 in the form of a wide strip, narrows and enters the inner screw perforated drum 18 for threshing and separation. The end hole of the receiving screw device 20 from the loading side is provided with a conical removable cover 24 (Fig. 1, Fig. 20, Fig. 21). The screw receiving device 20 is attached to the inner perforated drum 18 by a flange 87. Inside the screw device 20, five inserts 119 are fixed radially along the internal screw grooves 114, 115, 116, 117, 118, which not only provide rigidity to the fastening of the conical cover 24 (not shown in the drawing ) to the receiving screw device 20, but they also form a screw-like impeller along the inner perimeter of the receiving screw device 20, with the help of which the reliability of the transfer of the stalk mass to the inner the cavity of the receiving screw device 20 and, further, to the threshing and separation apparatus 10. The conical removable cover 24 is fastened with screws (not shown in the drawings) through holes 120 to the inserts 119, which are rigidly fastened, for example, by welding, inside the screw receiving device 20.

The receiving screw device 20 (Fig. 22, Fig. 23, Fig. 24) is made of five perforated strips 120, 121, 122, 123, 124 of a trapezoidal shape with different dimensions in width, with an increase in their length, twisted in a vertical plane in longitudinal direction relative to its own axis of symmetry of the perforated strip, for example, strip 120 (Fig.25), and curved along the helical line in the transverse direction on the conical mandrel 125 (Fig.26, Fig.27). After bending, the perforated strips 120, 121, 122, 123, 124 are connected to each other by the lateral sides by known methods, for example, by welding, with the formation of five helical lines along the perimeter of the receiving part and internal helical grooves with a variable, we decrease in length by step S ₆ , one of which 126-127 is shown in FIG. 22 with a thickened line. The receiving screw device 20 of the threshing apparatus 10 is provided with a flange 87. The diameter of the perforated holes of the receiving device 20 allows the passage of spikelets of grain crops along the length.

Combine harvester works as follows. Grain-straw mass slanted by the header 7 by the conveyor of the inclined chamber 8 is fed by known devices (not shown in the drawings) into the rotating threshing and separation apparatus 10, namely, through the receiving screw device 20, which with its five helical grooves and five inserts 119 forming the impeller transfers the stalk mass to the inner cavity of the inner screw perforated drum 18. When the screw receiving device 20 and the internal screw perforated drum 18 rotate the mass makes a complex spatial movement along helical paths and with the help of helical lines, helical surfaces moves along the horizontal axis of rotation of the inner screw drum 18. Thanks to the side walls of the double curvature of the drum of the receiving device 20 and rectangular pockets 108, 109, 110, 111, 112, 113 of the inner drum 18, which like blades capture portions of the stalk mass and lift them to a certain angle and throw towards each other and the perforated walls of the rotating inner perf oriented drum, the vectors of speed of movement of the stalk masses and spikelets change, which contributes not only to the intensity of separation of grain from spikelets, but also to the expansion of technological capabilities. Straw and other waste are removed outside the threshing and separation apparatus 10 through the outlet of the inner screw drum 18 from the discharge side. In this case, the grain and spikelets are removed outside the inner screw drum 18 and fall into the inner cavity of the middle multisection perforated drum 17. The speed of separation of grain and spikelets is intensified by different inclined sieves of the middle drum 17, which intensify the process of mixing grain and spikelets with each other and the separation of grain from spikelets . Grain and small impurities are separated from the floor and discharged into the inner cavity of the outer barrel drum 16, where they due to the natural slope of the walls of the barrel drum 16 move to the central part of the barrel drum 16, where perforated holes are located along the length L through which clean grain enters the screw 12 and then conveyor 9 is fed into the hopper (not shown in the drawings). The blower 11 supplies an air flow inside the end openings from the loading side into the cavity “B” between the middle drum 17 and the outer drum 16 and the cavity “A” between the inner drum 18 and the middle drum 17 to separate the chaff and litter from the grain and remove them outside the screw threshing and separation apparatus 10 through the end holes on the discharge side. Straw and other waste are removed through the end hole from the discharge side of the screw perforated drum 18.

Technical and economic advantages arise due to an increase in the frequency and energy consumption of the interaction of the stalk mass, spikelets not only with each other, but also with the inner walls of the inner screw drum 18, due to an increase in the cross-sectional area of the inner screw perforated drum 18 and the angle of inclination of the rectangular sifting pockets grain in the inner screw drum 18, which increases the mixing intensity, increases the energy intensity of the interaction of the stalk mass, spikelets, grain, AET performance and extends the technological capabilities combine.

Claims (1)

A combine harvester comprising a header, an inclined chamber, a blower and a threshing and separation apparatus equipped with a receiving screw device, made in the form of screw drums coaxially installed with a clearance, for example, three of the outer, middle and inner, and the outer drum is made with the formation of a multi-helical surface along the perimeter of three or more vertically folded in a vertical plane and sequentially interconnected strips of variable width of a convex curvilinear shape, folded in a vertical plane in the longitudinal direction, curved along helical lines in the transverse direction and bent along notches, with beveled walls in the transverse-longitudinal direction, arranged in pairs at an angle to each other on both sides of the strips with the formation along the perimeter of the drum of broken helical broken towards each other lines and broken helical surfaces with the same variable pitch along the length of the drum, and the middle drum is mounted from sections with the formation of a multi-helical surface made of n several equilateral perforated triangles in an even multiple of an even number, for example twelve, interconnected by two lateral sides, while the sections are connected to each other by the free third sides of the triangles with the formation of a helical drum, along the perimeter of which are broken right and left helical directed towards each other lines equipped with internal helical grooves directed towards each other with the same constant pitch along the length of the middle drum, while t the end openings of the screw drums on the loading side between the inner and middle drums, and also between the middle and outer drums are covered by a shell with the possibility of supplying air flow from the blower to them, while the end hole of the inner drum from the loading side is open, and the openings of all three drums are open from the unloading side and through the receiving screw device and the internal cavity of the internal screw drum passes the axis mounted on two supports supported by two beams housing harvester, characterized in that the inner drum is mounted from at least one rolled into cylindrical coils connected to each other along the longitudinal edges of the perforated strip, bent along the bending lines placed at an angle to its longitudinal edges, with the formation of the outer and inner surfaces of one-way helical lines and helical surfaces in the form of perforated pockets of a polygonal shape, the distance between the fold lines is equal to the length of each element of the polygon, while nye pockets along the inner surface may be different from the shape and dimensions of perforated pockets on the outer surface and the perimeter of the drum may vary not only in size but also in shape.

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