RU2517859C1 - Device for subsoil rotary milling with forced cleaning of mechanical drive and its cutting element from soil - Google Patents

Abstract

FIELD: agriculture.

SUBSTANCE: device comprises two rotary milling chisel ploughs located vertically symmetrically along the direction of travel of the device, mechanically connected to a common driver. The rotary milling chisel plough is provided with an annular milling chisel plough. The annular milling chisel plough is provided with outer cutting elements, provided along its outer side at the side surfaces alternately on the left and on the right. In front of the cutting element a container for receiving soil is made. The container for receiving soil is simultaneously a cavity of engagement of the gear drive on the outer side of the annular milling chisel plough. The container for receiving soil of the annular milling chisel plough is provided with a recess on its rear surface formed parallel to the plane of the annular milling chisel plough between the bottom of the container for receiving soil and the cutting element of the annular milling chisel plough. The rear surface in the direction of rotation of the pinion tooth is provided with a projection which width is 20-30% of the width of the pinion tooth, which lateral plane is made in one plane with the lateral surface of the tooth, directed towards the central plane of the pinion.

EFFECT: this constructive implementation enables to improve cleaning the container for receiving soil of the annular milling chisel plough and the cutting element of the annular milling chisel plough from the extracted soil, to reduce the tractive resistance and energy consumption, to improve reliability of the device.

2 cl, 2 dwg

Description

The invention relates to agricultural machinery and is intended for cutting water-absorbing gaps in the soil and subsoil loosening.

A device for rotary subsoil loosening, the drive of the milling machine in which is made in the form of a closed gearbox. (ed. St. USSR, No. 442759, IPC: АВВ 49/02, publ. 09/15/1974, bull. No. 34; inf. SK SKSTI, Rostov-Don, No. 101-74.43-75, 101 -76 - analogue).

The disadvantage of the drive is the need to move the gearbox through the soil in the technological process of rotational cultivation of the inner soil layer, which is due to the unproductive costs of additional energy that are not associated with the actual loosening (ПМС-70; ПМС-100; ПМС-100М; ФС-1,3; MSP-2, etc.).

The closest in technical essence to the claimed object is a device for rotational subsoil cultivation, containing two rotary cherezes located vertically symmetrically in the direction of movement of the device, mechanically associated with a common drive and an underground soil milling machine located below the drive, which have shafts located horizontally and perpendicular to the direction of movement cultivator (patent for the invention RU No. 2376737, C1, IPC AB 33/02, publ. 12/27/2009 - prototype).

This device has disadvantages:

- the cutting organ of annular cherese is made in the same plane with the rear surface of the soil receiving container, which worsens the conditions for cutting the soil from the side of the inner part of the soil receiving tank, since there is soil backwater from the bottom of the soil receiving tank;

- the tank for receiving soil, made on the outer side surface of the annular slit, is cleaned of the soil only in one direction by centrifugal force arising during the operation of the device, which makes it possible to clog the tank with soil and leads to additional energy consumption for tillage.

The technical problem, the solution of which will be provided by the present invention, consists in providing optimal conditions for cutting soil by cutting organs of annular shear, improving the cleaning from clogging with soil of containers for receiving soil, made on the outer side surface of the annular shear.

The technical result obtained by the practical use of the invention is the creation of the ability to produce when moving the device milling of the inner layers of the soil with high reliability and less energy.

To solve the technical problem, a device for intra-soil rotary milling with forced cleaning of the cutting tool of a mechanical drive from the ground is proposed. The device comprises a frame, two rotary cherezers located vertically symmetrically along the direction of movement of the device and mechanically connected with the common drive, and an underground soil milling machine located under the drive, which have shafts that are horizontal and perpendicular to the direction of movement of the cultivator. Rotary slitherese is equipped with a slitherese disk and annular slitherese. Ring slitherese is equipped with cutting bodies made on its lateral surfaces alternately left and right and directed towards its outer cylindrical surface. In front of the cutting body on the lateral surface of the annular slithere is a container for receiving soil. The tank for receiving soil of annular cherezeres is provided with a recess on its rear surface, made parallel to the plane of the annular cheresez between the bottom of the tank for receiving soil and the cutting organ of the annular cherese. The tooth surface of the tooth of the pinion gear is provided with a protrusion, the width of which is 20-30% of the width of the tooth of the pinion gear, the side plane of which is made in the same plane as the side surface of the tooth directed toward the central plane of the pinion gear.

The invention is illustrated by the attached drawing, where figure 1 shows the proposed device, side view, section BB; figure 2 - the proposed device, front view, section aa right in the direction of movement of the part of the device.

The device is made symmetrically with respect to the direction of movement, contains a frame 1, a rotary slitherez 2, an intra-soil milling machine 3 with milling cutters. Rotary slitherez 2 comprises a slitherese disk 4, an annular slitherese 5, a support 6, a centering 7 and a driven 8 of the drive gear. The subsoil milling machine 3 is installed in the driven gears 8 of the rotary slotters 2. An annular slitherese 5, which acts as a gearbox that transmits torque from the drive to the subsoil milling machine 3, is provided with spur gearing cavities made alternately on its lateral surfaces along the left and right along the inner cylindrical surface. 6, the centering 7 and driven 8 gears of the drive are made with outer teeth alternately located on the left and right along the outer cylindrical surface Nia 10, complementary inner engagement depressions 9 schelereza ring 5. Ring 5 schelerez inner cylindrical bearing surface rests in engagement with an outer cylindrical bearing surface of the support 6, 7 and the centering of the driven gear 8 of the drive. Each bearing surface of the corresponding kinematic drive element has a diameter equal to the corresponding diameter of the engagement circumference.

Ring slitherese 5 is made with cutting bodies 11 on its outer cylindrical surface, alternately left and right. In the direction of rotation of the annular slit 5 in front of the cutting body 11 on the side surface of the annular slit is made open on the side and in the direction of the outer cylindrical surface of the annular slit 5 a container for receiving soil 12.

The tank for receiving soil 12 is at the same time a depression of gearing of the gear drive on the outside of the annular cherese. The jumper between the right and left tanks for sequentially disposing on the annular slit 5 for receiving soil 12 simultaneously serves as the front surface of the meshing cavity.

The receptacle for receiving soil 12 of the annular slit 5 is provided with a recess 13. Recess 13 is made in the rear surface of the receptacle for receiving soil 12 parallel to the plane of the annular slit. The lateral surfaces of the recess are the inner surface of the tank for receiving soil 12 and the inner surface of the cutting organ of the annular shelherez.

The annular slitherese 5 has a gear drive from the drive pinion gear 14. The troughs of the gear in the form of a tank for receiving soil 12 are complementaryly connected to the gearing teeth 15, which are made alternately on the outer surface on the left (right) in the direction of rotation, respectively, of the ring slit 5 and the drive gear drive 14. The drive drive gear is mounted on the drive shaft, which is mounted on the frame 1 of the device. The drive gear of the actuator 14 is provided with teeth of the actuator 15 with projections 16.

The proposed device for rotary subsoil loosening works as follows.

When the device moves along the cultivated land, the torque is transmitted to the rotary slitherez 2. This is as follows. From the drive, the torque is supplied to the drive shaft through the gear, the engagement elements of the external drive of the ring sheare 4, the engagement elements 9 of the internal drive of the ring sheare 4, the engagement elements 10 of the driven gear 8 is supplied to the intra-soil milling machine 3 equipped with soil mills.

The annular slitherese 5 in the direction perpendicular to the plane of FIG. 1 is fixed in space alternately on the left and right, respectively, located on it, as well as on the support 6, centering 7 and 8 driven gears, meshing elements - meshing cavities 9 and meshing teeth 10. B the plane of FIG. 1, an annular slit 5 is positioned with its inner cylindrical supporting surface and the corresponding supporting surfaces of the supporting 6, centering 7 and the driven gear 8.

The torque is transmitted to the annular slit 5 by the teeth of the engagement 15 of the pinion gear 14 by means of the outer troughs of the engagement in the form of containers for receiving soil 12, made on the outer side surfaces of the annular slit 5.

Rotary slitherez 2 works from the bottom up, throwing the soil out of the face from itself and up. Ring slitherez 5 cutting organs 11 cuts a gap in the soil. Soil in the process of cutting from the cutting body 11 enters the container for receiving soil 12 located in the direction of rotation of the annular slit 5 in front of the cutting body 11. After lifting the container for receiving soil 12 above the soil surface, the soil is rotationally ejected from it onto the soil surface by centrifugal force. The container for receiving soil 12, made on the outer lateral surface of the annular cherese, is forcibly cleaned of the soil by extruding soil from it by means of a tooth, and inside the container there is no surface corresponding to the cavity of the tooth. Improving the cleaning of the tank for receiving soil is provided by the protrusion 16, which extracts from the tank an additional volume of soil stuck between the cutting member 11 of the annular slothere 5 and the inner surface of the tank for receiving soil 12.

The protrusion 16 also provides unhindered cutting by the cutting body 11 in the process of its next immersion in the face, since the cutting body 11 is previously cleaned. Therefore, there is no loss of energy on the release of the cutting body from the soil, stuck and adhering to the tank for receiving soil 12 near the cutting body 11. The process of cutting soil by the cutting body 11 in the face is more efficient, since the soil in the proposed technical solution leaves the tool in two directions, and not in one, as was the case in the well-known technical solution. This leads to a decrease in the likelihood of clogging of the tank 12 with soil. EFFECT: reduction of energy costs for tillage due to unhindered reception of the treated soil in the tank for receiving soil 12 of the annular slit 5 without compression and compaction.

In the proposed device, the low probability of clogging with soil containers for receiving soil 12 due to the following circumstances.

After the next capacity for receiving soil 12 from the bottom of the slit in the soil, the centrifugal discharge of soil from the capacity for receiving soil 12 occurs. Due to the lack of forced cleaning of the capacity for receiving soil 12, there is a chance of incomplete cleaning of the container for soil intake 12.

Then, the tank for receiving soil 12 is engaged with the gearing elements 15 of the drive gear of the drive 14, made complementary to the gear elements of the gear drive of the ring shear 5. The remaining soil is pushed out of the tank for receiving soil 12 with the tooth of the gear 12 of the drive gear of the drive 15.

The protrusion 16 improves the operation of the device in the second of the two considered phases of movement of the annular slitherese 5 above the day surface. The tank for receiving soil of annular slithereal 12 is provided with a recess 13 on its rear surface, made parallel to the plane of the annular slitherese between the bottom of the receptacle for receiving soil and the cutting organ of the ring slit. The tooth tooth surface of the pinion gear 15 is provided with a protrusion 16, the width of which is 20-30% of the width of the tooth of the pinion gear, the side plane of which is made in the same plane with the side surface of the tooth directed toward the central plane of the pinion gear. Due to the selected complementary shape of the protrusion 16 of the tooth gearing 15 of the pinion gear 14 and the recess 13 of the tank for receiving soil annular slitherea 12 is achieved complete cleaning of the tank for receiving soil. Also achieved is the release of the cutting edge of the cutting body 11 and the path of the descent from the soil at the next immersion in the face.

The proposed solution eliminates the clogging of soil containers for receiving soil 12. It also ensures the efficiency of the cutting organs of the annular shelhere 5.

As a result, the conditions for filling containers for receiving soil of annular slithereal are improved, and the resistance to rotation of the rotor in the soil is reduced. Accordingly, the traction resistance to movement decreases. The reliability of rotary slitherez 2 and the entire device is increased.

Using new elements in the form:

- recesses on the rear surface of the tank for receiving soil, made parallel to the plane of the annular shelieres between the bottom of the tank for receiving soil and the cutting body of the annular sheli,

- protrusion on the rear tooth surface of the leading gear tooth, the width of which is 20-30% of the width of the tooth of the driving gear, the side plane of which is made in the same plane as the side surface of the tooth directed towards the Central plane of the driving gear,

allows you to:

- when the device is moving, milling of the inner soil layers with low traction resistance of the slitherer reducer, decompress and mix the layers of the treated soil with each other, keep the humus layer and plant debris on the soil surface with high quality, reliability and lower energy costs,

- because it excludes clogging of soil-filled tanks on the outer side surface of the annular slitherez due to the use of its compulsory removal from the ground, the cutting organs of the annular slit are cleaned, the rotor rotation resistance in the soil is reduced, as well as the device’s movement resistance.

Claims (2)

1. A device for intra-soil rotary milling with forced cleaning of the mechanical drive and its cutting body from the ground, containing a frame, two rotary cherezes located vertically symmetrically along the direction of movement of the device and mechanically connected with the common drive and located below the drive by the underground milling machine, which have shafts, placed horizontally and perpendicular to the direction of movement of the cultivator, the rotary shelieres is equipped with a sheliere disk and annular shelieres, while the annular the slitherer is equipped with cutting bodies made on its lateral surfaces alternately left and right and directed towards its outer cylindrical surface, a soil receiving container is made in front of the cutting organ on the lateral surface of the annular slithere, characterized in that the annular slotry receiving ground is provided with a recess on its rear surface, made parallel to the plane of the annular cherezere between the bottom of the tank for receiving soil and the cutting organ of the annular cherese. 2. The device according to claim 1, characterized in that the tooth surface of the leading gear wheel of the mechanical drive is provided with a protrusion, the width of which is 20-30% of the width of the tooth of the driving gear, the side plane of which is made in the same plane with the side surface of the tooth directed towards the central plane of the pinion gear.

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