RU2374804C1 - Soil-cultivating wide-cut implement - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: invention is related to agricultural machine building, in particular to wide-cut sectional soil-cultivating machines, which are put into working and transport positions. Implement comprises hitch frame equipped with drag bar and brackets for installation of middle and extreme frames in transport position in front part and support wheels in back part, sections of working elements, central, two middle and two extreme frames, which are hingedly connected to each other, with central frame, with hitch frame and controlled by hydraulic cylinders through brackets rigidly fixed on frames and hitch frame. Each pair from extreme and middle frames with central frame is hingedly joined by means of two parallel installed four-link hinged mechanisms. The first crank of mentioned mechanism is created by bracket of central frame, upper and lower connecting rods connected to brackets of middle and extreme frames. Lower connecting rod by stem and base of hydraulic cylinder is additionally connected to bracket of central frame. Each section of working elements has shaft with set of working elements, bearing supports on shaft ends are mounted with the possibility of dismantling on longitudinal plates, which are mutually coupled by pair of transverse bars. In the middle of each transverse bar of section there is a bush welded-in, which by means of axis is mounted in bush on transverse bar of either central frame or middle frame or extreme frame. Coupling of coaxial bushes on transverse bars of working elements section and any frame by means of axis create a pendulum suspension, angular swaying of which is limited with limiter of working elements section rotation. Each frame is created with a pair of transverse bars, ends of which are coupled by longitudinal plates, having U-shaped cuts in upper part for matching in working position with lower connecting rods of four-link hinged mechanisms.

EFFECT: improved operational reliability and expanded scope of performed technological operations.

3 cl, 14 dwg

Description

The invention relates to agricultural machinery, in particular to wide-section sectional tillage machines, driven into working and transport positions.

The closest analogue to the claimed object in terms of technical means for implementing the proposed method of anti-erosion tillage is a tillage implement containing a gusset, a central, two middle and two extreme frames with sections of the working bodies, articulated to each other by eyes and fingers and controlled by hydraulic cylinders through brackets and support wheels rigidly fixed to the frames, in which, in order to increase operational reliability when moving the gun from the transport position to the working and vice versa, the eyes of the middle frames in the hinges of the connection with the extreme frames and the brackets of the extreme frames have arcuate grooves curved in opposite directions with a radius equal to the length of the arm of the bracket, while the eyes of the middle frames are provided with curved guides covering the ends of the arcuate grooves, and the fingers have elliptical heads rigidly fixed in the eyes of the extreme frames and in contact with the curved guide eyes (SU, copyright certificate No. 1475503 A1, M. class. ⁴ A01B 73/00. Tillage implement, 04/30/1989).

Despite the possibility of transferring the extreme and middle frames from the front position to the transport and lifting the extreme, middle and central frames to the transport position by rolling the support wheels under the frame, it has large dimensions in the transport position, and the implement has limited functionality.

The closest analogue to the claimed object is a wide erosion control tool, including a trailed earring and brackets for laying the middle and extreme frames in the transport position in the front and support wheels in the back of the gait, central, two middle and two extreme frames with sections of the working bodies, articulated between each other and the central frame with the grip and controlled by hydraulic cylinders through brackets rigidly mounted on the frames and grip, and support wheels on the middle frames (US Patent No. 6415873 B 1, IPC ⁷ АВВ 73/06 Anti-erosion wide-grip gun. - Application No. 091691929; Announced on 10/19/2000; Published on 09/07/2002).

The disadvantages of the described wide-sectional implement, which we adopted as the closest analogue, include high dynamic loads on the left and right brackets and middle frames when turning in the hydraulic actuator 28 in the hinges 42-42 due to the mismatch of the position of the support wheels 34 on the grip 12 and the support wheels 54 on the brackets of the middle sections 38 (see figures 4, 5, 8 and 9). When the wheels 54 are driven up by the middle frames of the sections 38, the central section 14 raises and twists the grip 12 by the wheels 54. This complicates the operation of the hydraulic actuators 50 and leads to breakdowns of the horizontal hinges 52 and 48. The implement has limited functionality. It does not have the ability to work with passive working bodies, incl. and with tooth harrows.

The essence of the claimed invention is as follows.

The problem to which the claimed invention is directed is to expand the functionality of a wide-spread tillage implement.

EFFECT: reduction of the implement’s dimensions in width and height and turning radius during transportation along field and highway roads, increasing operational reliability and expanding technological operations for soil cultivation (cover harrowing, pre-sowing cultivation, pre- and post-sowing rolling, vapor cultivation, mechanical suppression weeds of vegetation by discreters, leveling the topography of the soil, planar tillage, sowing of perennial crops and deep reclamation, volumetric hlenie overcrowded irrigated land).

The specified technical result is achieved by the fact that in the well-known wide tillage cultivating implement, including a trailed earring and brackets for laying in the transport position the middle and extreme frames in the front part and the support wheels in the back part of the tongue, sections of the working bodies, central, two middle and two extreme frames pivotally connected to each other, with a central frame, with a grip and controlled by hydraulic cylinders through brackets rigidly fixed to the frames and gland, according to the invention each pair of edges the lower and middle frames with the central frame are pivotally connected via parallel mounted four-link articulated mechanisms, the first crank of the said mechanism is formed by the bracket of the central frame, the upper and lower connecting rods connected to the brackets of the middle and extreme frames, while the lower connecting rod is additionally connected to the bracket by the rod and the base of the hydraulic cylinder the central frame, each section of the working bodies has a shaft with a set of working elements, bearing bearings at the ends of the shaft are mounted with the possibility of mounting on longitudinal plates mutually conjugated by a pair of transverse beams, while a sleeve is welded in the middle of each transverse beam of the section, which is mounted through the axis on the transverse beam of either the central frame, or the middle frame, or the extreme frame; the working bodies and any frame by means of axes form a pendulum suspension, the angular swings of which are limited by the rotation limiter of the working bodies section, each frame is formed by a pair of transverse bars, which are interlocked with longitudinal plates having U-shaped cutouts in the upper part for interfacing in the working position with the lower connecting rods of four-link articulated mechanisms; each limiter of rotation of the section of the working bodies relative to the transverse beam of either the left and right extreme frames, or the left and right middle frames, or the central frame is made in the form of a package of different-sized sheet elastic elements mounted above the transverse beam of the section of the working bodies and free ends mated with the upper face of the specified beam, while the package of different-sized sheet elastic elements by means of fastening is fixed in a bracket located on the upper edge of the transverse beam of the frame above the axis and the sleeve of the pendulum gimbal suspension; each limiter of rotation of the section of the working bodies relative to the transverse beam of either the left and right extreme frames, or the left and right middle frames, or the central frame is made in the form of a rope, the ends of which in the form of loops are mounted in U-shaped brackets of the transverse beam of the section of the working bodies, and the middle part of the rope through a horizontal slot is passed into the threaded hole of the supporting axis and fixed in it by means of a stopper, while the supporting axis by means of brackets is placed on the upper edge of the transverse beam and over the axle and the hub of the pendulum suspension.

The invention is illustrated by drawings.

Figure 1 shows in the working position, a tilling wide-spread implement, a plan view.

Figure 2 is the same side view.

Figure 3 is the same, rear view.

Figure 4 shows the process of translating the left extreme, left middle, central, right middle and right extreme frames when moving from the working position to the intermediate one before moving the extreme and middle frames to the transport position.

Figure 5 presents a tillage wide-grip implement in transport position, side view.

Figure 6 is the same plan view.

Figure 7 shows a section of the working bodies, rear view.

On Fig shows the left extreme frame assembly with a section of the working bodies, a plan view.

In Fig.9 cross section aa in Fig.8, a longitudinal section of the pendulum suspension section of the working bodies on the left extreme frame.

Figure 10 is a view B in figure 9, the pairing of the rotation limiter section of the working bodies relative to the transverse beams of the leftmost frame.

Figure 11 is the same, a variant of the design of the rotation limiter section of the working bodies relative to the transverse beams of the leftmost frame.

In Fig.12 - section GG in Fig.11, a diametrical section of the stopper of the rope.

In Fig.13 - place D in Fig.1, the position of the connecting rods of the four link articulated mechanisms on the central and left middle frames, a plan view.

On Fig - cross-section EE in Fig.13, fixing the lower connecting rods in the brackets of the longitudinal beams of the Central frame when performing the process.

Information confirming the possibility of implementing the claimed invention are as follows.

The tillage wide-grip implement (see Figs. 1-6) includes the gusset 1, sections 2 of the working bodies, the central frame 3, the two middle frames 4 and 5 and the two extreme frames 6 and 7. The grip 1 is equipped with a trailed earring 8 and brackets 9 and 10 for laying in the transport position of the middle frames 4, 5 and the extreme frames 6, 7 in the front of the gnome 1. In the rear of the gnome 1 there are support wheels 11.

The central frame 3 is pivotally connected to the snake 1 by means of rigidly fixed brackets 12 and 13 on the snivel 11 and the central frame 3 and is controlled by the hydraulic cylinder 14. The rod 15 of the hydraulic cylinder 14 is connected via the axis 16 to the bracket 17 of the central frame 3. The base of the hydraulic cylinder 14 is mounted with the finger 18 in the bracket on the central beam 19 of the tongue 1. On the central beam 19 of the tongue 1 brackets 9 and 10 are placed for laying frames 4, 5 and frames 6, 7.

Two extreme frames 6, 7 and two middle frames 4, 5 are pivotally connected to each other and to the central frame 3 and are controlled by hydraulic cylinders 20 and 21. The hydraulic cylinders 20 and 21 are pivotally mounted on the bracket 22 of the central frame 3.

Each pair of extreme 6 (7) and middle 4 (5) frames with a central frame 3 is pivotally connected by two parallel four-link articulated mechanisms 23 and 24. The mechanism 23 is mounted on the bracket 17 of the central frame 2, and the mechanism 24 is mounted on the bracket 22 of the aforementioned frames 3.

The first fixed crank of said mechanism 23 (24) is formed by a bracket 17 (22) of the central frame 3. The bracket 17 (22) is connected to the brackets 25 and 26 of the middle frame 4 (5) and the extreme frame 6 (7) of the upper 27 and lower 28 connecting rods. The lower connecting rod 28 by the bracket 29 of the mechanism 24 is connected with the rod 30 and the base of the hydraulic cylinder 20 (21) with the bracket 22 of the Central frame 3.

Each section 2 of the working bodies (see Fig. 7, 8, 9, 10, 11, 13, 14) has a shaft 31 with a set of working elements. As the working elements on the shaft 31, the teeth of the rotary working body (BIG-3), disks of the ring-spur roller (3KKSH-6A), cylinders of the water filling roller (3KVG-1,4), cutting knives of rotary working bodies, batteries can be sequentially equipped disk knives, etc. Bearing bearings 32 are mounted at the ends of the shaft 31. Bearing bearings 32 are fastened by means of fastening 33 to the longitudinal plates 34. For quick dismantling of the shaft 31 with working elements and bearing bearings 32, U-shaped slots 35 are made on the plates 34. Longitudinal plates S 34 is paired with a pair of transverse bars 36. In the middle of each transverse beam 36 of section 2, a sleeve 37 is welded. The plates 34 with the bars 36 and the sleeve 37 are connected by welds and form an integral unit. On the side faces of the bars 36, threaded holes 38 are made.

Each frame 3 (4, 5, 6, 7) (see Figs. 8, 9, 10, 11, 13 and 14) is formed by a pair of transverse bars 39 and a pair of longitudinal plates 40.

A sleeve 41 is mounted in the middle of each transverse beam 39. Threaded holes are made on the lateral faces of the transverse bars 39.

Sections 2 of the working bodies are placed with their transverse bars 36 and longitudinal plates 34 inside the frames 3, 4, 5, 6 and 7 and mated to each of them by means of axes 42. The axles 42 are fixed on the lateral faces of the transverse bars 39 by straps 43 and means of attachment from axial displacements.

The conjugation of the coaxial bushings 37 and 41 on the transverse bars 36 of the section 2 of the working bodies and the transverse bars 39 of the frames 3, 4, 5, 6 and 7 by means of the axes 42 form a pendulum suspension and this ensures the deviation of the working elements on the shaft 31 when copying the relief of the field. To perform technological operations with a given quality, each section 2 of the working bodies is equipped with a rotation limiter of the transverse bars 36 of section 2 relative to the transverse bars 39 of the frames 3-7. The angular rolling of the pendulum suspension is limited by the rotation limiter section 2 of the working bodies (see Fig.8-14).

Each limiter of the porosity of the section 2 of the working bodies, as an embodiment of the design, relative to the transverse beam 39 or the central frame 3, or the left and right middle frames 4 and 5, or the left and right extreme frames 6 and 7, is made in the form of a package 44 of different sheet and elastic elements (see Fig.9, 10, 13 and 14). A package 44 of elastic elements is mounted above the transverse beam 36 of the section 2 of the working bodies and the free ends of the elastic elements are paired with the upper face of the specified beam 36. The package 44 of different-sized sheet and elastic elements by means of fastening 45 is fixed in the bracket 46. The bracket 46 is placed on the upper edge of the transverse beam 39 frame 3 (4-7) over the axis 42 and the sleeve 41 of the swingarm.

Each rotation limiter of the section 2 of the working bodies relative to the transverse beam 36 (see Fig. 11 and 12), as an embodiment, to limit the angular rolling of the pendulum suspension relative to the transverse beam 39 or the left and right extreme frames 6 and 7, or left and right the middle frames 4 and 5, or the central frame 3 is made in the form of a rope 47. The ends of the rope 47 in the form of loops are mounted in U-shaped brackets 48 of the transverse beam 36 of section 2 of the working bodies. The middle part of the rope 47 (see Fig. 12) is passed through a horizontal slot 49 on the free end of the supporting axis 50. A threaded hole 51 with a tapered recess 52 is made in the supporting axis 50. The supporting axis 50 is placed by brackets 53 on the upper edge of the transverse beam 39 of the frames 3-7 above axis 42 and bushings 41 and 37 of the swingarm. The middle part of the rope 47 is fixed in the conical recess 52 of the supporting axis 50 by means of a threaded stopper 54. The threaded stopper 54 has a hemisphere 55 at one end and a square shank 56 at the other end to fit the size of the open end wrench.

In each frame 3, 4, 5, 6, and 7 (see Figs. 1, 8, 13, and 14 sequentially), at least one longitudinal plate 40 is coupled to the lower connecting rods 28 of four-link articulated mechanisms 23 and 24 for transmitting a part of the traction force of the aggregated tractor. These plates 40 in the upper parts have U-shaped cutouts 57 for mating in working position with the lower connecting rods 28 of four-link hinge mechanisms 23 and 24.

The connecting rods 27 and 28 with the front and rear transverse bars 39 of the frames 3-7 are connected by axles 58 and brackets 59.

Tillage widespread tool operates as follows.

In sections 2, working bodies can be installed for rolling the top soil layer with the creation of a flat surface, with hollows, with corrugated and other forms of microroughness, destruction of the turf, destruction of weeds, crop residues, loosening of the upper layer and alignment of macro- and microrelief.

Upon completion of any of the indicated technological operations, the machine operator puts the aggregate tractor's hydraulic spool with the middle handle of the spool of the hydraulic system. The rod 15 of the hydraulic cylinder 14 is drawn into the cavity of its base. The Central frame 3 by means of the axis 16 and the bracket 17 from a horizontal position due to the hinges in pairs of brackets 12 and 13 is rotated around their common axis of symmetry in a vertical position (see figure 2 and 4). Together with the central frame 3, the middle frames 4, 5 and the extreme frames 6 and 7 are simultaneously rotated. Sections 2 of the working bodies rise above the surface of the treated field to a height that allows the tool to move along the most difficult terrain.

Next, the machine operator engages in the “Lift” position the right and left handles of the hydroshock of the hydraulic system of the aggregated tractor. When the rod 30 of the hydraulic cylinder 20 is extended, the bracket 29 acts on the lower connecting rod 28 of the four-link articulated mechanism 23.

The lower connecting rod 28 under the influence of the force on the rod 30 of the hydraulic cylinder 20 rotates on the axis of the bracket 22 of the Central frame 3. The angular displacement of the lower connecting rod 28 through the brackets 25 and 26 leads to the rotation of the upper connecting rod 27 of the articulated mechanism 24 around a horizontal axis on the upper part of the bracket 22 of the Central frame 3 Due to the brackets 25 and 26, the lower and upper connecting rods 28 and 27 of the mechanism 23 are rotated synchronously located on the bracket 17 of the Central frame 3. Angular movements of the pairs of connecting rods 28 and 27 lead to the lifting of the brackets 25 and 26, and e with them plane-parallel rise of the middle frame 4 and the extreme frame 6 for the case of horizontal position of the Central frame 3 (see figure 3) above the field surface.

When the central frame 3 is upright (see FIGS. 4, 5 and 6 in sequence), the displacement of the connecting rods 27 and 28 leads to the movement of the frames 4 and 6 along the scaffold 1 towards the hooked earring 8. With the rod 30 of the frame 4 and 6 fully extended with sections 2 working bodies are located above the brackets 9 and 10 for stacking them in the transport position. Working in the same way as described by the right handle of the hydroshock of the hydraulic system of an aggregated tractor and the force on the rod 30 of the hydraulic cylinder 21, the right middle frame 5 and the extreme frame 7 are brought to the positions shown in Fig.6. For the final installation of frames 4, 5 and frames 6, 7, the machine operator brings the middle handle of the hydroshock of the aggregated tractor to the “Floating” position. Frames 4-7, under their own weight, are placed on the brackets 9 and 10 of the snits 1. Next, the frames 4, 5 and 6, 7 are fixed on the brackets 9 and 10. The left and right handles of the hydraulic rams are brought to the “Floating” position. Thus, before long-distance transportation, the rods 15 and 30 of the hydraulic cylinders 14, 20 and 21 are completely freed from power loads, as well as the high-pressure hoses connecting the cavities of the hydraulic cylinders 14, 20 and 21 with the hydraulic system 4 of the aggregated tractor.

Thanks to the mechanisms 23 and 24 and the articulation of the central frame 3 with the gland 1, sections 2 of the working bodies with their frames 3-7 are located above the gland (see Fig. 5), providing this gun with high clearance, small overall dimensions in width and height, high maneuverability when driving on field and highway roads. The translation of frames 3-7 is carried out by the machine operator without leaving the cab of an aggregated tractor.

From the stowed position of the frame 7, 6, 5, 4 and 3 to the working position are given in reverse order. To copy the terrain during the process, the rodless and rod cavities of the hydraulic cylinders 14, 20 and 21 are hydraulically connected by translating the handles of the hydraulic rams to the “Floating” position.

When carrying out a technological process, for example, pre-sowing rolling of the field relief under soybean crops, through the trailed earring 8, the scythe 1 moves on the support wheels 11. The traction force of the tractor being aggregated is transmitted to the central frame 3 by means of brackets 12, axles and brackets 13. A part of the tractor’s total traction force through the axes 42 on the bushings 41 of the transverse beams 39 of the central frame 3 is transmitted to the bushings 37 of the transverse beams 36 of section 2, and then through the longitudinal plates 34 to the bearing units 32 and the shaft 31. Thus, l 31 acts on the roller in section 2 and conducts soil compaction. On the upper soil layer during rolling of the roller in section 2, not only the force of weight from the mass of the roller, but the force of weight from the mass of the central frame 2 transmitted by the package of 44 elastic elements exerts. The pendulum suspensions of sections 2 in the central frame 3 of the gun provide satisfactory copying of the relief with a roller length of up to 2.2 m.

The tractor pulling force to the left and right middle frames 4 and 5 from the central frame 3 is transmitted by the lower connecting rods 28 of the front and rear mechanisms 23 and 24 both through the axles 58 in the brackets 59 and the U-shaped cutouts 57 in the plates 40 of the central frame 3 and the left the middle frame 4 (see Fig.13 and 14).

The pulling force of the tractor to the left and right extreme frames 6 and 7 from the connecting rods 27 and 28 is transmitted through the axles 58 in the brackets 59 and the U-shaped slots 57 in the plates 40 (see Fig. 8).

The limiters of turns support sections 2 of the working bodies in the required position inside frames 3-7 during long-distance transportation.

Claims (3)

1. Tillage wide-angle implement, including a trailed earring and brackets for laying in the transport position the middle and extreme frames in the front part and the support wheels in the rear part of the wedge, sections of the working bodies, the central, two middle and two extreme frames, hingedly connected to each other, with a central frame, with a grip and controlled by hydraulic cylinders through brackets rigidly fixed to the frames and gland, characterized in that each pair of the extreme and middle frames with the central frame is pivotally connected by two parallel mounted four-link hinge mechanisms, the first crank of the said mechanism is formed by the bracket of the central frame, the upper and lower connecting rods connected to the brackets of the middle and extreme frames, while the lower connecting rod is additionally connected to the bracket of the central frame by the rod and the base of the hydraulic cylinder, each section of the working bodies has a shaft with a set of working elements, bearing bearings at the ends of the shaft are mounted with the possibility of dismantling on longitudinal plates mutually conjugated by a pair of crossbars, while in the middle of each cross beam of the section a sleeve is welded, which is mounted through the axis on the cross beam, either the central frame, or the middle frame, or the extreme frame, the interface of the coaxial bushings on the transverse bars of the section of the working bodies and any frame by means of axes form a pendulum suspension, the angular swings of which are limited by the rotation limiter of the section of the working bodies, each frame is formed by a pair of transverse bars, the ends of which are joined by longitudinal plates having in the upper th part U-shaped cuts for mating in working position with the lower connecting rods of four-link articulated mechanisms. 2. Tillage wide-grip implement according to claim 1, characterized in that each rotation limiter of the section of the working bodies relative to the transverse beam of either the left and right extreme frames, or the left and right middle frames, or the central frame is made in the form of a package of different-sized sheet elastic elements installed above the transverse beam of the section of the working bodies, and the free ends are mated with the upper face of the specified beam, while the package of different-sized sheet elastic elements by means of fastening is fixed in the bracket, times eschennom on the upper face of the cross beam of the frame above the axle and the sleeve a pendulum suspension. 3. Tillage wide-angle implement according to claim 1, characterized in that each rotation limiter of the section of the working bodies relative to the transverse beam of either the left and right extreme frames, or the left and right middle frames, or the central frame is made in the form of a rope, the ends of which are in the form of loops sections of the working bodies are mounted in U-shaped brackets of the transverse beam, and the middle part of the rope is passed through the horizontal slot into the threaded hole of the supporting axis and fixed in it by means of a stopper, while supporting I axis by means of arms arranged on the upper face of the cross beam axis and the sleeve of the suspension pendulum.

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