LU506811B1 - Soil Saline Land Improvement Tilling Device and Method - Google Patents

Abstract

The invention discloses a soil saline land improvement tilling device and method, comprising a bracket assembly, characterized in that: the bracket assembly comprises a frame, the frame is fixedly connected to a front inclined plate, the front inclined plate is provided with a set of front leakage grooves uniformly distributed, the frame is connected to symmetrical side frames, the symmetrical side frames are respectively provided with a set of side grooves uniformly distributed, the frame is connected to a rear inclined plate, the rear inclined plate is provided with a set of evenly distributed rear leakage grooves, the rear inclined plate connects to a tail plate, the tail plate is set with a set of evenly distributed tail leakage grooves; the frame is set with a cross slot, the frame is fixedly connected to trapezoidal slots, the frame is connected to a cover, the cover is set with vertical slots. The invention relates to the technical field of soil saline land improvement, and specifically, relates to a soil saline land improvement tilling device and method. In order to solve the technical problems, the invention provides a soil saline land improvement tilling device and method to facilitate soil saline land improvement.

Description

Soil Saline Land Improvement Tilling Device and Method

LU50681 1

TECHNICAL FIELD

The invention relates to the technical field of soil saline land improvement, and specifically, relates to a soil saline land improvement tilling device and method.

BACKGROUND

Soil saline land is a type of land with salt accumulation, which means that the salt contained inside the soil affects the normal growth of crops. All kinds of saline soil are formed under certain natural conditions, and the essence of its formation is that various soluble salts are redistributed horizontally and vertically on the ground, and with the evaporation of soil moisture and crop consumption, the salts gradually accumulate on the soil surface. The main factors affecting the formation of saline soils are: climatic conditions, geographic conditions, soil texture and groundwater, the influence of rivers and seawater, and improper farming management.

Improvement of saline soils can be achieved by turning the soil, mixing the soil with amendments, and then filling the soil. However, stones and impurities turned out during soil improvement cannot be collected and disposed of.

SUMMARY

In order to solve the technical problems, the invention provides a soil saline land improvement tilling device and method to facilitate soil saline land improvement.

The invention adopts the following technical solution to realize the purpose of the invention: a soil saline land improvement tilling device and method, comprising a bracket assembly, characterized in that: the bracket assembly comprises a frame, the frame is fixedly connected to a front inclined plate, the front inclined plate is provided with a set of front leakage grooves uniformly distributed, the frame is connected to symmetrical side frames, the symmetrical side frames are respectively provided with a set of side grooves uniformly distributed, the frame is connected to a rear inclined plate, the rear inclined plate is provided with a set of evenly distributed rear leakage grooves, the rear inclined plate connects to a tail plate, the tail plate is set with a set of evenly distributed tail leakage grooves; the frame is set with a cross slot, the frame is fixedly connected to trapezoidal slots, the frame is connected to a cover, the cover is set with vertical slots; the frame is in bearing connection with a turning assembly, the turning assembly comprises a large shaft, the frame is in bearing connection with the large shaft, the large shaft is fixedly connected to rollers, the rollers are fixedly connected to a set of evenly distributed turning teeth; the cross slot is provided with an additive assembly, the additive assembly comprises symmetrically arranged cross blocks, the cross slot is provided with the symmetrical cross blocks, the symmetrical cross blocks are respectively fixedly connected to thin shafts, the symmetrical thin shafts are respectively fixedly connected to an L-frame, the symmetrical L-frames are respectively fixedly connected to a feed pipe; the symmetrical L-frames are respectively fixedly 06811 connected to a stone debris disposal assembly.

As a further limitation of the technical solution, the frame is fixedly connected to a power assembly, the power assembly comprises a dual-shaft motor, one output shaft of the dual-shaft motor is fixedly connected to a power bevel gear, the large shaft is fixedly connected to a follower bevel gear, and the follower bevel gear engages the power bevel gear.

As a further limitation of the technical solution, the other output shaft of the dual-shaft motor is fixedly connected to a turntable, the turntable is rotationally connected to a lower end of a power rod at an edge of the turntable, the trapezoidal groove is provided with a trapezoidal block, the trapezoidal block is fixedly connected to a round block axle, the upper end of the power rod is rotationally connected to the round block axle, the trapezoidal block is fixedly connected to a U- shaped axle, the U-shaped axle is rotationally connected to an end of symmetrical connecting rods, the other end of the symmetrical connecting rod is rotationally connected to the corresponding thin shaft respectively.

As a further limitation of the technical solution, the frame is rotationally connected to a pressure plate assembly corresponding to the rear inclined plate, the pressure plate assembly comprises a pressure plate, the pressure plate is fixedly connected to a symmetrical rotation shaft, the frame is rotationally connected to the symmetrical rotation shaft, the pressure plate is fixedly connected to a weight increasing block.

As a further limitation of the technical solution, the trapezoidal block is fixedly connected to a collision avoidance assembly, the collision avoidance assembly comprises a bending rod, the trapezoidal block is fixedly connected to the bending rod, the bending rod passes through the vertical groove, the bending rod is fixedly connected to a spring mounting seat, the spring mounting seat is fixedly connected to a press block by a spring.

As a further limitation of the technical solution, the stone debris disposal assembly comprises symmetrical mounting long blocks, the symmetrical L-frame is respectively fixedly connected to the corresponding mounting long blocks, the symmetrical mounting long blocks are respectively fixedly connected to a set of uniformly distributed blocks, the symmetrical mounting long blocks are respectively rotationally connected to a set of uniformly distributed wedge toggle plates, the wedge toggle plates matches the turning teeth.

As a further limitation of the technical solution, the stone debris disposal assembly comprises symmetrical mounting blocks, the symmetrical L-frames are respectively fixedly connected to the corresponding mounting blocks, the symmetrical mounting blocks are respectively fixedly connected to arc rods, the symmetrical arc rods are fixedly connected to a set of uniformly distributed arc knives, and a set of the arc knives matches the turning teeth.

As a further limitation of the technical solution, a set of the arc knives matches the corresponding side frames, and a set of the arc knives becomes longer sequentially from top to bottom.

A tilling method of a soil saline land improvement tilling device, characterized as comprising 06811 the steps of:

S1: mounting the frame to a mobile mechanism, where the mobile mechanism drives the unit to realize forward and backward movement as well as turning;

S2: installing a modifier storage box on the frame, where a material pump in installed on the modifier storage box, and the material pump is connected to the feed pipe through a hose;

S3: operating the moving mechanism to move and turn on the dual-shaft motor and the material pump;

S4: keeping the turning teeth to rotate to turn the soil;

S5: making the feed pipe reciprocate, spraying amendments reciprocally into the soil;

S6: rejecting stones by the stone debris disposal assembly into the side frame;

S7: allowing soil to slide down the rear ramp.

As a further limitation of the technical solution, the front leakage grooves, the side grooves, the rear leakage grooves and the tail grooves realize the fall of soil and stop the fall of stones.

Compared with the prior technology, the advantages and positive effects of the invention are: 1, the device realizes the turning of soil and the mixing with the improver by adopting the turning component and the adding component, the turning teeth keep rotating, turn the soil and drive the movement of stones and so on, and the feed pipe moves back and forth, spraying the improver back and forth into the soil, so that the soil and the improver follow the movement of the turning teeth, fall to the rear inclined plate, and move backward along the rear inclined plate, and the press plate follows the flow of the soil, and provides a certain pressure by its own gravity as well as by the gravity of the weight increasing block, squeezing the soil, and also realizes to a certain extent the mixing of the soil and the improver again; 2, when the device adopts wedge toggle plate, the wedge toggle plate moves in the downward direction (to move away from the centre of the roller), the block blocks wedge toggle plate, the wedge toggle plate does not oscillate and stays upright., the large pieces of rock debris are dialled out, the wedge toggle plate moves in the opposite direction, after contacting with the stone, oscillates under the influence of rocks, so that the wedge toggle plate moves over the stone, when the wedge toggle plate moves in the downward direction again, the stone blocks will be driven outward by contacting the stone blocks, after being pivoted by a plurality of wedge toggle plates, the stone falls into the side frame, which facilitates the realization of stone rejection; and 3, when the device adopts the arc knives, a set of arc knives becomes longer from top to bottom, gradually close to the side frame, the lower cut surface of the arc knives coincides with the outer surface of the turning teeth at a suitable distance from the outer surface of the turning teeth. Soil passes through the hollows, and the large stone debris moves along the curved surface of the arc knives, and finally rolls into the side frames on both sides.

BRIEF DESCRIPTION OF THE FIGURES LU506811

FIG. 1 shows a schematic diagram 1 of the three-dimensional structure of the invention.

FIG. 2 shows a schematic diagram 2 of the three-dimensional structure of the invention.

FIG. 3 shows a schematic diagram of the three-dimensional structure of the bracket assembly of the invention.

FIG. 4 is a schematic diagram of the three-dimensional structure of the bracket assembly of the invention in partial section.

FIG. 5 shows a schematic diagram 1 of a partially dissected three-dimensional structure of the invention |.

FIG. 6 shows a schematic diagram of the partial three-dimensional structure of the stone debris disposal assembly of the present invention.

FIG. 7 shows a schematic diagram 2 of the partial three-dimensional structure of the invention.

FIG. 8 shows a schematic diagram 3 of the three-dimensional structure of the invention.

In the figures: 1: bracket assembly; 11: frame; 12: front inclined plate; 13: front leakage groove; 14: side frame; 15: side groove; 16: rear inclined plate; 17: rear leakage groove; 18: tail plate; 19: tail leakage groove; 110: cover; 111: vertical slot; 112: cross slot, 113: trapezoidal slot, 114: front shovel; 2: stone debris disposal assembly; 21: wedge toggle plate; 22: block; 23: mounting long block; 24: mounting block; 25: arc rod; 26: arc knife; 3: additive assembly; 31: L-frame; 32: feed pipe; 33: thin shaft; 34: cross block; 35: connecting rod; 4: turning assembly; 41: follower bevel gear; 42: large shaft; 43: roller; 44: turning teeth; 5: collision avoidance assembly; 51: bending bar; 52: spring mounting seat; 53: spring; 54: press block; 6: press plate assembly; 61: weight increasing block; 62: pressure plate; 63: rotation shaft; 7: power assembly; 71: power rod; 72: turntable; 73: dual-shaft motor; 74: power bevel gear; 75: trapezoidal block; 76: U-shaped shaft; 77: round block shaft.

DESCRIPTION OF THE INVENTION

Specific embodiments of the invention are described in detail below in connection with the accompanying figures, but it should be understood that the scope of protection of the invention is not limited by the specific embodiments.

The invention comprises a bracket assembly 1, the bracket assembly 1 comprises a frame 11, the frame 11 is fixedly connected to a front inclined plate 12, the front inclined plate 12 is provided with a set of uniformly distributed front leakage grooves 13, the frame 11 is connected to symmetrical side frames 14, the symmetrical side frames 14 is respectively provided with a set of uniformly distributed side grooves 15, the frame 11 is connected to a rear inclined plate 16, he 506811 rear inclined plate 16 is provided with a set of uniformly distributed rear leakage grooves 17, the rear inclined plate 16 is connected to a tail plate 18, the tail plate 18 is provided with a set of uniformly distributed tail leakage slots 19; the frame 11 is provided with cross slots 112, the frame 5 11 is fixedly connected to trapezoidal slots 113, the frame 11 is connected to a cover 110, the cover 110 is provided with vertical grooves 111; the frame 11 is in bearing connection with a turning assembly 4, the turning assembly 4 comprises a large shaft 42, the frame 11 is in bearing connection with the large shaft 42, the large shaft 42 is fixedly connected to a roller 43, the roller 43 is fixedly connected to a set of uniformly distributed turning teeth 44; the cross slot 112 is provided with an additive assembly 3, the additive assembly 3 comprises symmetrical cross blocks 34, the cross slot 112 is provided with the symmetrical cross blocks 34, the symmetrical cross blocks 34 are respectively fixedly connected to thin shafts 33, the symmetrical thin shafts 33 are respectively fixedly connected to an L-frame 31, the symmetrical L-frames 31 are respectively fixedly connected to a feed pipe 32; the symmetrical L-frames 31 are respectively fixedly connected to a stone debris disposal assembly 2.

The frame 11 is fixedly connected to a power assembly 7, the power assembly 7 comprises a dual-shaft motor 73, one output shaft of the dual-shaft motor 73 is fixedly connected to a power bevel gear 74, the large shaft 42 is fixedly connected to a follower bevel gear 41, and the follower bevel gear 41 engages the power bevel gear 74.

The other output shaft of the dual-shaft motor 73 is fixedly connected to a turntable 72, the turntable 72 is rotationally connected to the lower end of a power rod 71 at the edge of the turntable 72, the trapezoidal groove 113 is provided with a trapezoidal block 75, the trapezoidal block 75 is fixedly connected to a round block axle 77, the upper end of the power rod 71 is rotationally connected to the round block axle 77, the trapezoidal block 75 is fixedly connected to a U-shaped axle 76, the U-shaped axle 76 is rotationally connected to one end of a symmetrical connecting rod 35, and the other end of the symmetrical connecting rod 35 is rotationally connected to the corresponding thin shaft 33 respectively.

When the dual-shaft motor 73 works, it drives the power bevel gear 74 and the turntable 72 to rotate, the power bevel gear 74 drives the driven bevel gear 41 to rotate, the driven bevel gear 41 drives the large shaft 42 to rotate, the large shaft 42 drives the roller 43 to rotate, and the roller 43 drives the turning teeth 44 to rotate, realizing that the turning teeth 44 turn over the soil, so that the soil is stored in the area between the two turning teeth 44, and the turntable 72 drives the power rod 71 to reciprocate, the turntable 72 drives the power lever 71 to swing back and forth, the power lever 71 drives the round block axle 77 to move back and forth, the round block axle 77 drives the trapezoidal block 75 to move back and forth along the trapezoidal slots 113, the trapezoidal block 75 drives the U-shaped axle 76 to move back and forth, the U-shaped axle 76 drives the connecting rod 35 to swing back and forth, the connecting rod 35 drives the thin shaft 33 to move back and forth, the thin shafts 33 drive the cross blocks 34 to move back and forth along the cross groove 112, and the thin shaft 33 drives the L-frame 31 and the feed pipe 321506811 moves back and forth, the feed pipe 32 sprays the amendment back and forth into the soil to realize mixing of the soil with the amendment, and the L-frame 31 drives the stone debris disposal assembly 2 to move back and forth.

Embodiment 1: the stone debris disposal assembly 2 comprises symmetrical mounting long blocks 23, the symmetrical L-frame 31 are fixedly connecting corresponding the mounting long blocks 23 respectively, the symmetrical mounting long blocks 23 are fixedly connected to a set of uniformly distributed blocks 22 respectively, the symmetrical mounting long blocks 23 are rotatingly connected to a set of uniformly distributed wedge toggle plates 21 respectively, the wedge toggle plates 21 match the turning teeth 44.

The wedge toggle plates 21 move in the downward direction (when moving away from the centre of the rollers 43), the block 22 blocks the wedge toggle plate 21, the wedge toggle plates 21 does not oscillate and keeps upright, and the large stone debris is set aside, the wedge toggle plates 21 move in the reverse direction, after contacting the stone, they oscillate under the hindering effect of the stone, so that the wedge toggle plates 21 cross the stone, and the wedge toggle plate 21 move in the downward direction again when contacting the stone to drive the stone blocks to move outwardly, and after a plurality of wedge toggle plates 21 are toggled, the stone blocks fall into the side frame 14.

Embodiment 2: the stone debris disposal assembly 2 comprises symmetrical mounting blocks 24, the symmetrical L-frames 31 are fixedly connected to the corresponding mounting blocks 24, the symmetrical mounting blocks 24 are fixedly connected to a arc rod 25, symmetrically the arc rod 25 is fixedly connected to a set of uniformly distributed arc knives 26, a set of the arc knives 26 matches the toggle teeth 44.

One set of the arc knives 26 matches the corresponding side frame 14, and one set of the arc knives 26 is sequentially longer from top to bottom.

When a stone block follows the movement of the turning teeth 44, it gradually contacts the arc knives 26 and moves outwardly along the arc knives 26, and the arc knives 26 pushes the stone block into the side frame 14 with the reciprocating movement.

Embodiment 3: this embodiment is further elaborated on the basis of embodiment 1 or 2, the frame 11 is rotationally connected to a pressure plate assembly 6 corresponding to the rear inclined plate 16, the pressure plate assembly 6 comprises a pressure plate 62, the pressure plate 62 is fixedly connected to a symmetrical rotation shaft 63, the frame 11 is rotationally connected to a symmetrical rotation shaft 63 of the rotation axis, and the pressure plate 62 is fixedly connected to a weight increasing block 61.

The trapezoidal block 75 is fixedly connected to a collision avoidance assembly 5, the collision avoidance assembly 5 comprises a bending rod 51, the trapezoidal block 75 is fixedly connected to the bending rod 51, the bending rod 51 passes through the vertical groove 111, the bending rod 51 is fixedly connected to a spring mounting seat 52, the spring mounting seat 52 18 506811 fixedly connected to a press block 54 by means of a spring 53.

When the dual-shaft motor 73 is working, the trapezoidal block 75 drives the bending rod 51, the spring mounting seat 52, the spring 53 and the pressure block 54 to move up and down reciprocally, the soil turned over by the turning teeth 44 is largely dropped onto the rear inclined plate 16, a part of the soil falls down from the rear leakage groove 17, and the other part of the soil moves backwardly along the rear inclined plate 16, and the pressure plate 62 follows the direction of the flow of the soil, and relies on its own gravity and that of the weight increasing block 61 to provide a certain pressure to squeeze the soil, when the pressure block 54 contacts the oscillating weight increasing block 61, a cushion is realized by the spring 53 to prevent excessive soil flow and lifting up the pressure plate 62 and crashing the upper structure. A small portion of the soil falls onto the front inclined plate12 and fall from the front leakage groove 13.

Embodiment 4: this embodiment is further elaborated on the basis of embodiment 1 or 2 or 3, the frame 11 is connected to a front shovel 114.

When this device is used with the soil turned over by a tilling machine in front of it, the height of this device should be controlled in such a way that the front shovel 114 in front can be moved in the downward direction to shovel in the soil that needs to be treated as the best.

Driven by the tractor and other mobile organizations, this device shovels into the soil to be treated, the soil enters the front inclined plate 12, and the soil moves rearwardly under the action of the turning teeth 44 when it contacts the turning assembly.

A tilling method of a soil saline land improvement tilling device, characterized as comprising the steps of:

S1: mounting the frame 11 to a mobile mechanism, where the mobile mechanism drives the unit to realize forward and backward movement as well as turning;

S2: installing a modifier storage box on the frame 11, where a material pump in installed on the modifier storage box, and the material pump is connected to the feed pipe 32 through a hose;

S3: operating the moving mechanism to move and turn on the dual-shaft motor 73 and the material pump;

S4: keeping the turning teeth 44 to rotate to turn the soil;

S5: making the feed pipe 32 reciprocate, spraying amendments reciprocally into the soil;

S6: rejecting stones by the stone debris disposal assembly 2 into the side frame 14; and

S7: allowing soil to slide down the rear inclined plate 16.

The front leakage grooves 13, the side grooves 15, the rear leakage grooves 17 and the tail grooves 19 realize the fall of soil and stop the fall of stones.

The device realizes the turning of soil and the mixing with the improver by adopting the turning component 4 and the adding component 3, the turning teeth 44 keep rotating, turn the soil and drive the movement of stones and so on, and the feed pipe 32 moves back and forth, spraying the improver back and forth into the soil, so that the soil and the improver follow the movement of the turning teeth 44, fall to the rear inclined plate 16, and move backward along the rear inclined, 06811 plate 16, and the press plate 62 follows the flow of the soil, and provides a certain pressure by its own gravity as well as by the gravity of the weight increasing block 61, squeezing the soil, and also realizes to a certain extent the mixing of the soil and the improver again.

When the device adopts wedge toggle plate 21, the wedge toggle plate 21 moves in the downward direction (to move away from the centre of the roller 43), the block 22 blocks the wedge toggle plate 21, the wedge toggle plate 21 does not oscillate and stays upright., the large pieces of rock debris are dialled out, the wedge toggle plate 21 moves in the opposite direction, after contacting with the stone, oscillates under the influence of rocks, so that the wedge toggle plate 21 moves over the stone, when the wedge toggle plate 21 moves in the downward direction again, the stone blocks will be driven outward by contacting the stone blocks, after being pivoted by a plurality of wedge toggle plates 21, the stone falls into the side frame 14, which facilitates the realization of stone rejection.

When the device adopts the arc knives 26, a set of arc knives 26 becomes longer from top to bottom, gradually close to the side frame 14, the lower cut surface of the arc knives 26 coincides with the outer surface of the turning teeth 44 at a suitable distance from the outer surface of the turning teeth 44. Soil passes through the hollows, and the large stone debris moves along the curved surface of the arc knives 26, and finally rolls into the side frames 14 on both sides.

The above disclosure describes only specific embodiments of the invention, however, the invention is not limited thereto, and any changes that can be contemplated by any person skilled in the art shall fall within the scope of protection of the invention.

Claims (10)

CLAIMS LU50681 1

1. À soil saline land improvement tilling device, comprising a bracket assembly (1), characterized in that: the bracket assembly (1) comprises a frame (11), the frame (11) is fixedly connected to a front inclined plate (12), the front inclined plate (12) is provided with a set of front leakage grooves (13) uniformly distributed, the frame (11) is connected to symmetrical side frames (14), the symmetrical side frames (14) are respectively provided with a set of side grooves (15) uniformly distributed, the frame (11) is connected to a rear inclined plate (16), the rear inclined plate (16) is provided with a set of evenly distributed rear leakage grooves (17), the rear inclined plate (16) connects to a tail plate (18), the tail plate (18) is set with a set of evenly distributed tail leakage grooves (19); the frame (11) is set with a cross slot (112), the frame (11) is fixedly connected to trapezoidal slots (113), the frame (11) is connected to a cover (110), the cover (110) is set with vertical slots (111); the frame (11) is in bearing connection with a turning assembly (4), the turning assembly (4) comprises a large shaft (42), the frame (11) is in bearing connection with the large shaft (42), the large shaft (42) is fixedly connected to roller (43), the roller (43) are fixedly connected to a set of evenly distributed turning teeth (44); the cross slot (112) is provided with an additive assembly (3), the additive assembly (3) comprises symmetrical cross blocks (34), the cross slot (112) is provided with the symmetrical cross blocks (34), the symmetrical cross blocks (34) are respectively fixedly connected to thin shafts (33), the symmetrical thin shafts (33) are respectively fixedly connected to an L-frame (31), the symmetrical L-frames (31) are respectively fixedly connected to a feed pipe (32); the symmetrical L-frames (31) are respectively fixedly connected to a stone debris disposal assembly (2).

2. The soil saline land improvement tilling device according to claim 1, characterized in that: the frame (11) is fixedly connected to a power assembly (7), the power assembly (7) comprises a dual-shaft motor (73), one output shaft of the dual-shaft motor (73) is fixedly connected to a power bevel gear (74), the large shaft (42) is fixedly connected to a follower bevel gear (41), and the follower bevel gear (41) engages the power bevel gear (74).

3. The soil saline land improvement tilling device according to claim 2, characterized in that: the other output shaft of the dual-shaft motor (73) is fixedly connected to a turntable (72), the turntable (72) is rotationally connected to a lower end of a power rod (71) at an edge of the turntable (72), the trapezoidal groove (113) is provided with a trapezoidal block (75), the trapezoidal block (75) is fixedly connected to a round block axle (77), the upper end of the power rod (71) is rotationally connected to the round block axle (77), the trapezoidal block (75) is fixedly connected to a U-shaped axle (76), the U-shaped axle (76) is rotationally connected to an end of symmetrical connecting rods (35), the other end of the symmetrical connecting rod (35) Is, 506811 rotationally connected to the corresponding thin shaft (33) respectively.

4. The soil saline land improvement tilling device according to claim 3, characterized in that: the frame (11) is rotationally connected to a pressure plate assembly (6) corresponding to the rear inclined plate (16), the pressure plate assembly (16) comprises a pressure plate (62), the pressure plate (62) is fixedly connected to a symmetrical rotation shaft (63), the frame (11) is rotationally connected to the symmetrical rotation shaft (63), the pressure plate (62) is fixedly connected to a weight increasing block (61).

5. The soil saline land improvement tilling device according to claim 4, characterized in that: the trapezoidal block (75) is fixedly connected to a collision avoidance assembly (5), the collision avoidance assembly (5) comprises a bending rod (51), the trapezoidal block (75) is fixedly connected to the bending rod (51), the bending rod (51) passes through the vertical groove (111), the bending rod (111) is fixedly connected to a spring mounting seat (52), the spring mounting seat (52) is fixedly connected to a press block (54) by a spring (53).

6. The soil saline land improvement tilling device according to claim 5, characterized in that: the stone debris disposal assembly (2) comprises symmetrical mounting long blocks (23), the symmetrical L-frames (31) are respectively fixedly connected to the corresponding mounting long blocks (23), the symmetrical mounting long blocks (23) are respectively fixedly connected to a set of uniformly distributed blocks (22), the symmetrical mounting long blocks (23) are respectively rotationally connected to a set of uniformly distributed wedge toggle plates (21), the wedge toggle plates (21) matches the turning teeth (44).

7. The soil saline land improvement tilling device according to claim 6, characterized in that: the stone debris disposal assembly (2) comprises symmetrical mounting blocks (24), the symmetrical L-frames (31) are respectively fixedly connected to the corresponding mounting blocks (24), the symmetrical mounting blocks (24) are respectively fixedly connected to arc rods (25), the symmetrical arc rods (25) are fixedly connected to a set of uniformly distributed arc knives (26), and a set of the arc knives (26) matches the turning teeth (44).

8. The soil saline land improvement tilling device according to claim 7, characterized in that: a set of the arc knives (26) matches the corresponding side frames (14), and a set of the arc knives (26) becomes longer sequentially from top to bottom.

9. A tilling method of a soil saline land improvement tilling device according to claim 6, characterized as comprising the steps of: S1: mounting the frame (11) to a mobile mechanism, where the mobile mechanism drives the unit to realize forward and backward movement as well as turning; S2: installing a modifier storage box on the frame (11), where a material pump in installed on the modifier storage box, and the material pump is connected to the feed pipe (32) through a hose;

S3: operating the moving mechanism to move and turn on the dual-shaft motor (73) and the 506811 material pump; S4: keeping the turning teeth (44) to rotate to turn the soil; S5: making the feed pipe (32) reciprocate, spraying amendments reciprocally into the soil; S6: rejecting stones by the stone debris disposal assembly (2) into the side frame (14); S7: allowing soil to slide down the rear ramp (16).

10. A tilling method according to claim 9, characterized in that: the front leakage grooves (13), the side grooves (15), the rear leakage grooves (17) and the tail grooves (19) realize the fall of soil and stop the fall of stones.