RU2159031C1 - Rotor drive reducer for licorice extraction machine - Google Patents

Abstract

FIELD: agriculture. SUBSTANCE: reducer has output shaft 4, pair of oppositely arranged cone gears 33, 34. Both gears are continuously meshed with similar cone gears 35, 36 mounted on cantilevered parts of input and intermediate shafts 2, 3 of reducer. Output shaft 4 is equipped with two opposite output shanks 23, 24. Output shaft 4 is mounted in casing 1 of reducer in position perpendicular to output shaft 2. The latter has movable unit composed of three cylindrical gears 9, 10, 11 which are mounted for alternative engagement with two gears 17, 18 on intermediate shaft 3 and built-in cylindrical gear 38 with inner engagement in cone gear 35 on cantilevered part of input shaft 2. Such construction allows torque to be divided into two currents, when torque variation stage number is increased. EFFECT: simplified construction and increased efficiency. 3 cl, 1 dwg

Description

 The invention relates to agricultural machinery, in particular to drives of heavily loaded rotary working bodies of agricultural machines.

 Known vehicle creeper, comprising a housing, input, intermediate and output shafts with mounted cylindrical gears, one of which is mounted on the shaft movably with the possibility of interaction with the gear teeth on the intermediate shaft (SU, 743900, class B 60 K 17/06 , 1980).

 The disadvantage of this device: limited functionality - the implementation of only one step of changing the moment with the relative complexity of the design - and the impossibility of distributing the moment into two streams.

 The closest invention to the proposed one is a rotor drive reducer of a machine for the extraction of licorice roots, containing input and output shafts with gears mounted on them (RU 2125785, class A 01 D 25/02, 02/10/99).

 The disadvantage of this machine: limited functionality - the implementation of the process with the relative complexity of the design - and the inability to distribute the moment into two streams.

 The invention consists in the following.

 The problem to which the invention is directed is the expansion of functionality by increasing the number of stages of change in moment.

 The technical result is the distribution of torque into two streams with an increase in the number of stages of change in torque.

 The specified technical result in the implementation of the invention is achieved by the fact that on the output shaft, equipped with two opposite output shanks and mounted perpendicular to the input shaft, is mounted opposite through a distance washer a pair of bevel gears that are in constant engagement with similar bevel gears mounted on the console sections of the input and intermediate shafts, while the input shaft is equipped with a movable block of three cylindrical gears installed with the possibility of w alternately coupling with the two gears on the intermediate shaft and integral cylindrical internal gear in the bevel gear on the cantilevered portion of the input shaft.

 The invention is illustrated by the drawing, which shows a horizontal section of the input, intermediate and output shafts, and the movable gear block is engaged with the driven spur gear of the second overdrive.

 Information confirming the possibility of carrying out the invention are as follows.

 The rotor drive gear of the licorice root extraction machine includes a housing 1, an input shaft 2, an intermediate 3 and an output 4 shafts. The input shaft 2 is equipped with a receiving splined shank 5 with an annular groove 6, straight-line splines 7 for installing a movable block 8 of three cylindrical gears 9, 10 and 11 of different diameters, seats 12 and 13 to accommodate bearing bearings 14 and 15. On the intermediate shaft 3 motionless due to straight-line slots 16 two gears 17 and 18 are fixed with the possibility of alternating interaction with gears 9 and 10 of block 8, respectively. Seats 19, 20 are made at the ends of the intermediate shaft 3 to accommodate bearing bearings 21 and 22. Output the 4th shaft 4 is equipped with two opposite output shanks 23 and 24 with annular grooves 25 and 26. With offset to the middle of the output shaft 4, seats 27 and 28 are made to accommodate the bearing bearings 29 and 30. The middle section of the shaft 4 is provided with straight-side splines 31. The output shaft 4 in the housing 1 is installed perpendicular to the input shaft 2. In the middle splined part of the output shaft 4, a pair of equal bevel gears 33 and 34 are oppositely mounted through a distance washer 32. Both gears 33 and 34 are in constant engagement with the same gears For instructions bevel gears 35 and 36 mounted on cantilevered portions respectively input 2 and 3, the intermediate shaft. At the end of the input shaft 2, the bevel gear 35 is freely set. The hub 37 of the bevel gear 35 is mounted on the input shaft 2 by means of a radial bearing 15 at the seat 13, and the outer side of the hub 37 together with the built-in gear 38 is mounted in the housing 1 on two opposed bevel bearings 39 and 40. A movable block 8 of three cylindrical gears 9, 10 and 11 on the splines 7 of the input shaft 2 is installed with the possibility of alternating interaction with two gears 17 and 18 of the intermediate shaft 3, as well as the third gear 11 m smaller diameter with built-in bevel gear 35, on the cantilever part of the input shaft 2, a cylindrical gear 38 with internal gearing. The hub of block 8 is provided with a groove 41 in which the fork 42 of the mechanism for moving the movable block 8 of gears 9-11 is located. A spacer sleeve 43 is mounted between the cylindrical gears 17 and 18 on the intermediate shaft 3. The hub of the bevel gear 36 on the cantilever part of the intermediate shaft 3 is fixed from the axial displacement by the disk 44 and the locking bolts 45. The locking bolts 45 are located in the threaded holes on the shaft end 3 and are mutually connected retainer. Bearings 39 and 40 in housing 1 are mounted by cup 46. Between bearings 39 and 40 in cup 46 is an expansion sleeve 47. Bearings 39 and 40 are secured with a shaped nut 48 and a washer with a mustache on the threaded portion of the hub 37 of the bevel gear 35. The position of the hub 37 is bevel gears 35 on the radial bearing 15 are fixed by a locking ring 49. The axial displacement of the bevel gear 35 relative to the cantilever part of the input shaft 2 is limited by the disk 50 and the locking bolts 51 in the threaded holes of the shaft end 2. The glasses 52, 53, 46, 54, 55 and 56, respectively but bearing supports 21, 14, 39 and 40, 22, 30 and 29 of the intermediate, the input and output shafts 2, 3 and 4 are mounted in the housing 1 with the possibility of disassembly. Glasses 54 and 46 are mounted on the partition 57 of the housing 1.

 With the cover of the housing 1 removed and the cups 46 and 54 removed, between the baffle 57 and the rear wall of the housing 1 and between the baffle 57 and the front wall, a bevel gear 35 and a movable block 8 of the spur gears 9, 10 and 11 mounted on the input shaft 2 are installed. the outer ring of the roller bearing 39, the spacer sleeve 47 and the outer ring of the roller bearing 40 are successively installed in the cup 46. Next, the inner rings of the bearings 39 and 40 are installed on the hub 37 by pressing fit. On the threaded part of the hub 37 of the conical stubble 35 is screwed shaped washer 48 through the washer with mustache. The tightness of the nut 48 is checked by rotating the cup 46 relative to the hub 37. Then one of the whiskers is bent into the matching groove of the shaped nut. The light ball bearing 15 is mounted in the hub cavity 37 for easy press fit. The displacement of the deep groove ball bearing 15 in the hub cavity 37 is limited by the retaining ring 49 installed in the annular groove of the hub 37. Next, the hub 37 of the bevel gear 35 with the built-in gear 38 is oriented towards the straight-line splines 7 of the input shaft 2 from the seat 13. The bearing 15 is mounted on the seat 13 of the input shaft 2 and fix its position using the disk 50 and the locking bolts 51. The hub of the block 8 of the cylindrical pole Ren 9-11 is installed on straight-line slots 7 from the side of the seat 12. Next, the receiving splined shank 5 of the input shaft 2 is inserted into the window of the front wall of the housing 1. The glass 46 is mounted on the partition 57 of the housing 1. The glass 53 together with the deep groove ball bearing 14 are mounted on the landing place 12 of the input shaft. The glass 53 is attached to the housing 1. In the glass 53 install the bearing cover with shims. The axial displacement of the input shaft 2 is limited by the latter. Similarly, the intermediate shaft 3 is installed in the housing 1. The adjusting gaskets installed between the blank cover and the cup 52 adjust the clearance in the roller bearings 21 and 22 and in the engagement of the teeth of the bevel gears 36 and 33. Before this adjustments in the housing 1 install the output shaft 3 and the opposing pair of gears 33 and 34.

 With the cover removed, a pair of bevel gears 33 and 34 and a distance washer 32 are inserted from top to bottom. Then the glasses 55 and 56 are attached to the side walls of the housing 1. Into one of the glasses, for example, into the glass 56, the output shank 24 of the output shaft 4 is inserted. Next, on the splines 31 of the shaft 4, the bevel gear 33, the spacer 32 and the bevel gear 34 are sequentially mounted. From the cups 56 and 55, the outer and inner rings and cages of the roller bearings 27 and 28 are mounted on the seats 27 and 28. The cups 56 and 55 are attached to case 1. Set metal spacers installed between the through covers and cups 56 and 55, adjust the clearance in the engagement of the teeth of the bevel gears 34 and 35. With a normal contact spot between the teeth of the bevel gears 34 and 35, the covers are finally fixed in the cups 55 and 56. The adjustment is completed by checking the engagement teeth in bevel gears 33 and 36. This is achieved by the distance washer 32 and the gasket between the blind cover and the glass 52. After adjustments are complete, check the tightness of the housing 1 in conjunction with the glasses 52, 53, 55 and 56.

 Then check the operation of the moving mechanism of the movable block 8. After that, close the lid of the housing 1. Through the filler plug, the cavity of the housing 1 is filled with gear oil to the level of the control plug. On the cover of the housing 1 check the condition of the breather. The gearbox is ready for operation.

 The gear drive rotor of the machine for the extraction of licorice roots works as follows.

 The gearbox is mounted on the frame of the machine and kinematically connected to a heavily loaded extractor rotor that processes the soil layer with an area of 0.7 x 1.1 m. Due to the difficult operating conditions, torque is supplied to the rotor from two sides. The gearbox is driven by the tractor PTO. Torque is supplied to the receiving splined shank 5 of the input shaft 2 through the universal joint of the Hook of the universal joint telescopic shaft of the machine.

 Depending on the operating conditions of the machine - soil (light sandy, heavy over-dried, soil and waterlogged soil); dry steppe or floodplain licorice ecotype; structural features of the root system and its placement in soil horizons; time and season of work; productivity and size (diameter, length) of the roots and rhizomes of licorice - the rotor of the machine, therefore, the gearbox, must provide various modes of operation, i.e. the gearbox must have three steps of changing the magnitude of the torque.

In the machine extraction of licorice roots and rhizomes, which have raw and commercial value (Glycyrrhiza glabra L. or Glycyrrhiza uralensis Fisch.), The root extraction machine is aggregated with tractors of draft class 30-60 kN equipped with independent power take-off shafts (PTO). The shaft speed is 9 s ^-1 or 17 s ^-1 (540 or 1020 rpm). Changing the PTO speed of tractors in the field is not possible. This operation is difficult and time-consuming even in specialized workshops.

 A direct transmission from the input shaft 2 to the output shaft 4 is formed when the smallest cylindrical gear 11 of the gear unit 8 of gears 9-11 is engaged with the gear 38 (with internal gearing) integrated in the bevel gear 35 freely fitted on the input shaft 2. B In this embodiment, gears 11 and 38 form a gear clutch, providing blocking - connection with the input shaft 2 - of the bevel gear 35. After blocking, the moment from the input shaft 2 is transmitted through the bevel gear 35 to the bevel gear which is constantly engaged with it nude 34 and to the output shaft 4. The hub 37 of the bevel gear 35 and the gear 38 integrated therein rotate relative to the cup 46 and the housing 1 on the tapered bearings 39 and 40. Next, the moment passes through the output splined shanks 23 and 24 on the output shaft 4 by means of an additional transmission ( not shown) is transmitted to the rotor of the machine for the extraction of licorice roots. At the same time, the bevel gear 33 on the output shaft 4 rotates the bevel gear 36, which is engaged with it, on the intermediate shaft 3. The latter, together with the cylindrical gears 17 and 18 mounted on it, rotates idle.

 The second (up) gear in the gearbox is formed when the largest cylindrical gear 10 of block 8 with a fork 42 of the movement mechanism on the input shaft 2 is engaged with a gear 18 of a smaller diameter on the intermediate shaft 3. In this embodiment, the moment from the input shaft 2 through gears 10 and 18 it is transmitted to the intermediate shaft 3, which drives the bevel gear 36 fixed at the end of this shaft into rotation. The latter transfers the moment through the bevel gear 33 to the output shaft 4 and its output shanks 23 and 24. At the same time, m another bevel gear 34 on the output shaft 4 drives the bevel gear 35, which is unlocked relative to the output shaft 2, and rotates the latter (together with the spur gear 38) freely rotates relative to the input shaft 2 - on the radial bearing 15, and relative to the housing 1 and the cup 46 - on opposite mounted roller bearings 39 and 40.

 The third (lower) transmission in the gearbox is formed when the middle-diameter cylindrical gear 9 of the block 8 of the movable gears 9-11 with the fork 42 of the movement mechanism on the input shaft 2 is shifted towards the receiving splined shank 5 and is engaged with the gear 17 of the largest diameter on the intermediate shaft 3. In this embodiment, the moment from the input shaft 2 is transmitted through gears 9 and 17 to the intermediate shaft 3, which drives the bevel gear 36 fixed on the end of this shaft, to rotate. The latter through the bevel pole The shaft 33 transmits the moment to the output shaft 4 and its output shanks 23 and 24. Thus, the greatest torque is created on the shaft 4.

Claims (3)

 1. The rotor drive gear of a machine for the extraction of licorice roots, containing input and output shafts with gears mounted on them, characterized in that on the output shaft, equipped with two opposing output shanks and mounted perpendicular to the input shaft, is oppositely mounted through a distance washer of a pair of bevel gears in constant engagement with similar bevel gears mounted on cantilever sections of the input and intermediate shafts, while the input shaft is equipped with movable a block of three cylindrical gears are mounted for alternate coupling to the two gears on the intermediate shaft and integral cylindrical internal gear in the bevel gear on the cantilevered portion of the input shaft.  2. The gearbox according to claim 1, characterized in that the hub of the bevel gear is mounted on the input shaft by means of a radial bearing, and the outer side of the hub, together with the built-in gear, is installed in the housing on two opposed bevel bearings.  3. The gearbox according to claim 1, characterized in that the bearing cups of the input, intermediate and output shafts are mounted in the housing with the possibility of dismantling.