CN113417977B - Gearbox structure of reversing gear - Google Patents

Abstract

The invention belongs to the technical field of gearboxes, and particularly relates to a gearbox reverse gear structure of a gearbox reverse gear structure, which is characterized in that: the planetary gear is arranged on a planetary carrier through a shaft; the planet carrier can move axially and is respectively meshed with the output shaft and the shell at two limit positions; when the carrier is engaged with the housing, power is transmitted to the output shaft through the ring gear. The invention realizes reverse rotation by utilizing the planetary gear ring of the auxiliary box, cancels the reverse gear set and the connecting device thereof, reduces the length of the gearbox and the number of parts, and has the advantages of less parts, convenient operation, low cost and reliable quality.

Description

Gearbox structure of reversing gear

Technical Field

The invention belongs to the technical field of gearboxes, and particularly relates to a gearbox reverse gear structure.

Background

Chinese patent "a motor drive dog clutch formula car structure of reversing gear", publication No. CN106151486A, it is 2016.11.23 to disclose a motor drive dog clutch formula car structure of reversing gear, including the input shaft, the input shaft middle part is installed in the first sleeve through the bearing, the first sleeve is installed on the fixed flat plate, be fixed with the dog clutch on the fixed flat plate left side, first sleeve left side and second deep groove ball bearing inner circle be clearance fit, the second deep groove ball bearing passes through the second sleeve and links to each other with the planet carrier, the outer flank of planet gear and input shaft that the planet carrier is connected, the internal tooth face meshing of output wheel, the planet carrier outside links to each other with the shift fork, install lead screw nut on the shift fork, the output shaft of motor is connected to the lead screw nut, adjust the position of planet carrier, can make the right side tooth of planet carrier mesh with the left side tooth of dog clutch, or the left side tooth of planet carrier meshes with the right side tooth of output wheel, or planet carrier and output wheel disengage, simultaneously the planet carrier also disengages with the dog clutch, realize the function of reversing gear of car, the control mode is reliable, the cost is low.

When the automobile gear shifting device is used, the input shaft is connected with the internal combustion engine and the motor, the output wheel is connected with the gearbox, when the automobile gear shifting device needs to work at a reverse gear position, the motor is used as a power source of the gear shifting mechanism to perform rotary motion, the output shaft of the motor drives the screw nut to perform axial translational motion, the translational motion of the screw nut is transmitted to the planet carrier through the shifting fork, the horizontal position of the planet carrier can be changed by controlling the motor, when the planet carrier translates rightwards until right teeth of the planet carrier are meshed with left teeth of the jaw clutch, the output wheel and the input shaft rotate in a speed reduction mode in the opposite direction, and the speed reduction and reverse gear shifting function of the automobile is achieved.

The Chinese patent 'reverse gear assembly for gearbox', publication No. CN203730674U, grant bulletin date 2014.07.23, discloses a reverse gear assembly for gearbox, which belongs to the field of engineering machinery. The power input shaft is provided with a sun gear, and the first gear assembly comprises a first gear planet shaft, a first gear planet carrier, a first gear piston and a first gear inner gear ring; the reverse gear assembly comprises a reverse gear planetary shaft, a reverse gear planetary carrier, a reverse gear piston, a reverse gear inner gear ring, and a driven friction plate and a driving friction plate which are sequentially arranged at intervals; the first-gear planetary shaft and the reverse-gear planetary shaft are respectively provided with a planetary wheel which is matched with the sun wheel; the sun gear adopts positive displacement plus 0.275, and the reverse gear inner gear ring, the first gear planet carrier and the first gear inner gear ring adopt negative displacement minus 0.1821; the planet wheel adopts positive displacement plus 0.2685.

When a reverse gear is engaged, pressure oil pushes a reverse gear piston to move right to press five driven friction plates and four driving friction plates, a reverse gear planet carrier is fixed, power is transmitted through a sun gear, and is transmitted to a direct gear pressure disc through a planet gear, a reverse gear inner gear ring and a first gear planet carrier to be output; when a first gear is engaged, pressure oil pushes a first gear piston to move left to press five driven friction plates and five driving friction plates, a first gear planet carrier is fixed, a first gear inner gear ring is fixed by a friction plate set, power is transmitted through a sun gear, and is transmitted to a direct gear pressure receiving disc through a planet gear and the first gear planet carrier to be output.

Chinese patent "a speed change mechanism", publication No. CN103899717A, published date 2014.07.02 discloses a speed change mechanism, including input device, output device, shell and install in planetary gear mechanism in the shell, planetary gear mechanism includes planet carrier and planetary gear, the planet carrier fixed set up in inside the shell, be provided with on the planet carrier planetary gear, input device pass through planetary gear mechanism with output device connects. The reversing gear is added, the reverse gear action of a vehicle and the like can be realized, the requirement in the driving process of the vehicle is met, and the vehicle is more humanized.

The reverse gear of the 'one speed change mechanism' is realized as follows: the output shaft external splines of output shaft and counter gear's internal splines link up, the input shaft passes through the input shaft external gear and drives one-level planetary gear and rotate, one-level planetary gear drives the planet carrier and rotates, the planet carrier drives the second grade planetary gear who is connected with the planet carrier ring gear and rotates, second grade planetary gear drives counter gear and rotates to drive the output shaft reversal, can realize the reverse gear action of vehicle etc. satisfy the demand of vehicle driving in-process, it is more humanized.

Chinese patent "a tractor gearbox switching mechanism that reverses gear", publication number CN209688006U, the grant announcement day 2019.11.26 disclose a tractor gearbox switching mechanism that reverses gear, including planetary gear set, dc-to-ac converter, controlling device, planetary gear set is double planetary gear, and its structure includes ring gear, sun gear, outer planet wheel, interior planet wheel and planet carrier, the dc-to-ac converter includes fixed gear and switching-over cover, controlling device includes power input shaft and control rod, planet carrier is connected with outer planet gear, interior planet gear, the embedded fixed connection of fixed gear and planet carrier, power input shaft and sun gear fixed connection, the installation that the switching-over cover passes through spline movable about on the power input shaft, control rod and switching-over cover fixed connection.

The working principle that the double-row planetary gear set is matched with the inverter is adopted, and the forward gear and the reverse gear are the same in number. The operating rod pushes right to drive the reversing sleeve to move right, the reversing gear is meshed with the fixed gear, power opposite to the power input shaft is input to the planet gear carrier, the outer planet gear and the inner planet gear are driven to overturn under the action of the planet gear carrier, and the tractor runs backwards, so that the reverse gear of the gearbox of the tractor is quickly switched.

The multiplication that current heavy many grades of gearboxes generally adopted main tank + NGW planet auxiliary box structure to realize the velocity ratio, and the auxiliary box has two to keep off: the transmission device comprises a low gear, a high gear, a gear ring, an auxiliary box, a planetary gear and a planet carrier, wherein the gear ring is connected with an output shaft when the high gear is in high gear, the gear ring is fixed when the low gear is in low gear, power is transmitted to the output shaft through the sun gear, the planetary gear and the planet carrier, and the planet carrier and the output shaft are integrated into a whole. Since the carrier speed is the revolution speed, a large reduction ratio can be obtained. The existing heavy multi-gear gearbox reverse gear scheme: the power of the engine passes through the normally meshed gear set and the reverse gear set, and is output to the axle and the wheels after being subjected to low-gear gradual speed reduction through the auxiliary box. The reverse gear set is arranged in the main box to realize the rotation speed reversal of the engine.

The main box needs to be provided with a reverse gear set, a jointing device of the reverse gear set, a control lever system and the like, so that the length and the cost of the gearbox are increased, the gear shifting is complex, and the arrangement difficulty is high.

Disclosure of Invention

The invention aims to provide a reverse gear structure of a gearbox, which has the advantages of reduction of the length of the gearbox, no gear shift, low cost and convenience in installation.

In order to achieve the purpose, the invention designs a reverse gear structure of a gearbox, which is characterized in that: the planetary gear is arranged on a planetary carrier through a shaft; the planet carrier can axially move and is respectively meshed with the output shaft and the shell at two limit positions; when the carrier is engaged with the housing, power is transmitted to the output shaft through the ring gear.

Preferably, a reverse gear connecting piece is arranged on the planet carrier and is connected with the operating lever; the reverse gear connecting piece can be meshed with the shell.

Further preferably, the reverse gear connecting piece is engaged with a two-shaft bearing cover provided on the housing.

Further preferably, a gear shifting groove is formed in the outer wall of the reverse gear connecting piece and connected with the operating rod.

Preferably, a guide ring is arranged between the hole wall of the planet carrier and the outer wall of the output shaft; a snap ring is arranged between the guide ring and the planet carrier; the outer diameter of the guide ring is larger than the inner diameter of the clamping ring and smaller than the outer diameter of the clamping ring.

Further preferably, at least two trapezoidal grooves for accommodating the snap ring are formed in the inner wall of the planet carrier. In this way, the extreme positions of the axial displacement of the planet carrier are defined by the two trapezoidal grooves.

Further preferably, the guide ring is provided with an annular groove for accommodating the snap ring, and the inner diameter of the annular groove is smaller than that of the snap ring.

Still further preferably, a first gap is formed between part of the inner wall of the guide ring and the output shaft; the output shaft is provided with a first oil hole which is radially arranged and communicated with the first gap, and the guide ring is provided with a second oil hole which is communicated with the first gap and the annular groove. Therefore, the function of lubricating the snap ring is achieved, and the planet carrier is convenient to operate to move.

Still further preferably, a second gap is provided between the guide ring and the carrier, and a third oil hole for communicating the second gap with the first gap is provided in the guide ring. In this way, it acts to lubricate the synchronizer and the bearings.

The beneficial effects of the invention are:

1. the planetary gear ring of the auxiliary box is utilized to realize reverse rotation, a reverse gear set and a connecting device thereof are eliminated, the length of the gearbox and the number of parts are reduced, and the cost of the gearbox is reduced.

2. The guide ring is matched with the clamping ring to form a positioning structure, so that reliable positioning before and after gear shifting of the planet carrier is guaranteed, and gear disengagement is prevented.

3. And a pressure lubricating oil passage is arranged between the positioning contact surfaces between the guide ring and the planet carrier, so that abrasion is prevented.

4. The reverse gear external engaging teeth are integrated on the bearing cover, so that the number of parts is reduced, and the installation is convenient.

5. The invention reduces the length and weight of the gearbox, has less parts, convenient operation, low cost and reliable quality.

Drawings

FIG. 1 is a prior art schematic

FIG. 2 is a schematic representation of the present invention

FIG. 3 is a schematic representation of the present invention before reverse engagement

FIG. 4 is an enlarged schematic view at A in FIG. 3

FIG. 5 is a schematic representation of the present invention after reverse engagement

In the figure: 1. a constant mesh gear set; 2. a first gear group; 3. a housing; 4. a two-axis bearing cap; 5. a planet carrier; 6. a sun gear; 7. a planet wheel; 8. a ring gear; 9. a shaft; 10. a snap ring; 11. a guide ring; 12. a gear sleeve; 13. a high-grade conical ring; 14. a main oil pipe; 15. and an output shaft.

Detailed Description

The technical solutions of the present invention (including the preferred technical solutions) are further described in detail by means of fig. 2 to 5 and a way of listing some alternative embodiments of the present invention. It is to be understood that the described embodiments are merely a few embodiments of the invention, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments of the present invention without inventive step, shall fall within the scope of protection of the present invention.

In the description of the present invention, "a plurality" means two or more unless otherwise specified; the terms "upper", "lower", "left", "right", "inner", "outer", "front", "rear", "head", "tail", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are merely for convenience in describing the present invention and to simplify the description, and do not indicate or imply that the device or element referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

Example one

As shown in fig. 2 to 5, the reverse gear structure of the transmission designed by the invention comprises a sun gear 6, a planet gear 7 meshed with the sun gear 6, and a gear ring 8 meshed with the planet gear 7, wherein the planet gear 7 is mounted on a planet carrier 5 through a shaft; the planet carrier 5 can move axially and is respectively meshed with the output shaft 15 and the shell 3 at two limit positions; when the carrier 5 is engaged with the housing 3, power is transmitted to the output shaft 15 through the ring gear 8.

A reverse gear connecting piece is arranged on the planet carrier 5 and is connected with the operating lever; the reverse gear connection can engage with the housing 3.

A guide ring 11 is arranged between the hole wall of the planet carrier 5 and the outer wall of the output shaft; a clamping ring 10 is arranged between the guide ring 11 and the planet carrier 5; the outer diameter of the guide ring 11 is larger than the inner diameter of the snap ring 10 and smaller than the outer diameter of the snap ring 10.

The outer wall of the reverse gear connecting piece is provided with a gear shifting groove, and the gear shifting groove is connected with the operating rod.

Example two

As shown in fig. 2 to 5, the reverse gear structure of the transmission designed by the invention comprises a sun gear 6, a planet gear 7 meshed with the sun gear 6, and a gear ring 8 meshed with the planet gear 7, wherein the planet gear 7 is arranged on a planet carrier 5 through a shaft; the planet carrier 5 can move axially and is respectively meshed with the output shaft 15 and the shell 3 at two limit positions; when the carrier 5 is engaged with the housing 3, power is transmitted to the output shaft 15 through the ring gear 8.

The reverse gear connecting piece is engaged with a two-shaft bearing cover 4 arranged on the shell 3.

The outer wall of the reverse gear connecting piece is provided with a gear shifting groove, and the gear shifting groove is connected with the operating rod.

EXAMPLE III

As shown in fig. 2 to 5, the reverse gear structure of the transmission designed by the invention comprises a sun gear 6, a planet gear 7 meshed with the sun gear 6, and a gear ring 8 meshed with the planet gear 7, wherein the planet gear 7 is arranged on a planet carrier 5 through a shaft; the planet carrier 5 can axially move and is respectively meshed with the output shaft 15 and the shell 3 at two limit positions; when the carrier 5 is engaged with the housing 3, power is transmitted to the output shaft 15 through the ring gear 8.

A guide ring 11 is arranged between the hole wall of the planet carrier 5 and the outer wall of the output shaft; a clamping ring 10 is arranged between the guide ring 11 and the planet carrier 5; the outer diameter of the guide ring 11 is larger than the inner diameter of the snap ring 10 and smaller than the outer diameter of the snap ring 10.

At least two trapezoid grooves for accommodating the snap ring 10 are arranged on the inner wall of the planet carrier 5. In this way, the extreme positions of the axial displacement of the planet carrier 5 are defined by the two trapezoidal grooves.

Example four

As shown in fig. 2 to 5, the reverse gear structure of the transmission designed by the invention comprises a sun gear 6, a planet gear 7 meshed with the sun gear 6, and a gear ring 8 meshed with the planet gear 7, wherein the planet gear 7 is arranged on a planet carrier 5 through a shaft; the planet carrier 5 can move axially and is respectively meshed with the output shaft 15 and the shell 3 at two limit positions; when the carrier 5 is engaged with the housing 3, power is transmitted to the output shaft 15 through the ring gear 8.

A guide ring 11 is arranged between the hole wall of the planet carrier 5 and the outer wall of the output shaft; a snap ring 10 is arranged between the guide ring 11 and the planet carrier 5; the outer diameter of the guide ring 11 is larger than the inner diameter of the snap ring 10 and smaller than the outer diameter of the snap ring 10.

At least two trapezoid grooves for accommodating the snap ring 10 are arranged on the inner wall of the planet carrier 5. In this way, the extreme positions of the axial displacement of the planet carrier 5 are defined by the two trapezoidal grooves.

The guide ring 11 is provided with an annular groove for accommodating the snap ring 10, and the inner diameter of the annular groove is smaller than that of the snap ring 10.

A first gap 15c is formed between part of the inner wall of the guide ring 11 and the output shaft 15; the output shaft 15 is provided with a first oil hole 15b radially arranged to communicate with the first gap 15c, and the guide ring 11 is provided with a second oil hole 11b communicating the first gap 15c with the annular groove 11 a. Thus, the function of lubricating the snap ring 10 is achieved, and the planet carrier 5 is convenient to operate and move.

A second gap is formed between the guide ring 11 and the planet carrier 5, namely the guide inner hole 5d, and a third oil hole 11c for communicating the second gap, namely the guide inner hole 5d, with the first gap 15c is formed in the guide ring 11. In this way, it acts to lubricate the synchronizer and the bearings.

EXAMPLE five

As shown in fig. 2 to 5, the reverse gear structure of the transmission designed by the invention comprises a sun gear 6, a planet gear 7 meshed with the sun gear 6, and a gear ring 8 meshed with the planet gear 7, wherein the planet gear 7 is mounted on a planet carrier 5 through a shaft; the planet carrier 5 can axially move and is respectively meshed with the output shaft 15 and the shell 3 at two limit positions; when the carrier 5 is engaged with the housing 3, power is transmitted to the output shaft 15 through the ring gear 8.

A reverse gear connecting piece is arranged on the planet carrier 5 and is connected with the operating lever; the reverse gear connection can engage with the housing 3.

The outer wall of the reverse gear connecting piece is provided with a gear shifting groove, and the gear shifting groove is connected with the operating rod.

A guide ring 11 is arranged between the hole wall of the planet carrier 5 and the outer wall of the output shaft; a clamping ring 10 is arranged between the guide ring 11 and the planet carrier 5; the outer diameter of the guide ring 11 is larger than the inner diameter of the snap ring 10 and smaller than the outer diameter of the snap ring 10.

At least two trapezoid grooves for accommodating the snap ring 10 are arranged on the inner wall of the planet carrier 5. In this way, the extreme positions of the axial displacement of the planet carrier 5 are defined by the two trapezoidal grooves.

The guide ring 11 is provided with an annular groove for accommodating the snap ring 10, and the inner diameter of the annular groove is smaller than that of the snap ring 10.

A first gap 15c is formed between part of the inner wall of the guide ring 11 and the output shaft 15; the output shaft 15 is provided with a first oil hole 15b radially arranged to communicate with the first gap 15c, and the guide ring 11 is provided with a second oil hole 11b communicating the first gap 15c with the annular groove 11 a. Thus, the function of lubricating the snap ring 10 is achieved, and the planet carrier 5 is convenient to operate and move.

A second gap is formed between the guide ring 11 and the planet carrier 5, namely the guide inner hole 5d, and a third oil hole 11c for communicating the second gap, namely the guide inner hole 5d, with the first gap 15c is formed in the guide ring 11. In this way, it acts to lubricate the synchronizer and the bearings.

EXAMPLE six

As shown in fig. 2 to 5, the reverse gear structure of the transmission designed by the invention comprises a sun gear 6, a planet gear 7 meshed with the sun gear 6, and a gear ring 8 meshed with the planet gear 7, wherein the planet gear 7 is arranged on a planet carrier 5 through a shaft; the planet carrier 5 can axially move and is respectively meshed with the output shaft 15 and the shell 3 at two limit positions; when the carrier 5 is engaged with the housing 3, power is transmitted to the output shaft 15 through the ring gear 8.

A reverse gear connecting piece is arranged on the planet carrier 5 and is connected with the operating lever; the reverse gear connection can engage with the housing 3.

The reverse gear connecting piece is engaged with a two-shaft bearing cover 4 arranged on the shell 3.

The outer wall of the reverse gear connecting piece is provided with a gear shifting groove, and the gear shifting groove is connected with the operating rod.

A guide ring 11 is arranged between the hole wall of the planet carrier 5 and the outer wall of the output shaft; a snap ring 10 is arranged between the guide ring 11 and the planet carrier 5; the outer diameter of the guide ring 11 is larger than the inner diameter of the snap ring 10 and smaller than the outer diameter of the snap ring 10.

The guide ring 11 is provided with an annular groove for accommodating the snap ring 10, and the inner diameter of the annular groove is smaller than that of the snap ring 10.

EXAMPLE seven

As shown in fig. 2 to 5, the reverse gear structure of the transmission designed by the invention comprises a sun gear 6, a planet gear 7 meshed with the sun gear 6, and a gear ring 8 meshed with the planet gear 7, wherein the planet gear 7 is arranged on a planet carrier 5 through a shaft; the planet carrier 5 can move axially and is respectively meshed with the output shaft 15 and the shell 3 at two limit positions; when the carrier 5 is engaged with the housing 3, power is transmitted to the output shaft 15 through the ring gear 8.

A reverse gear connecting piece is arranged on the planet carrier 5 and is connected with the operating lever; the reverse gear coupling can engage with the housing 3.

The reverse gear connecting piece is engaged with a two-shaft bearing cover 4 arranged on the shell 3.

The outer wall of the reverse gear connecting piece is provided with a gear shifting groove, and the gear shifting groove is connected with the operating rod.

A guide ring 11 is arranged between the hole wall of the planet carrier 5 and the outer wall of the output shaft; a clamping ring 10 is arranged between the guide ring 11 and the planet carrier 5; the outer diameter of the guide ring 11 is larger than the inner diameter of the snap ring 10 and smaller than the outer diameter of the snap ring 10.

At least two trapezoidal grooves for accommodating the snap ring 10 are arranged on the inner wall of the planet carrier 5. In this way, the extreme positions of the axial displacement of the carrier 5 are defined by the two trapezoidal grooves.

The guide ring 11 is provided with an annular groove for accommodating the snap ring 10, and the inner diameter of the annular groove is smaller than that of the snap ring 10.

A first gap 15c is formed between part of the inner wall of the guide ring 11 and the output shaft 15; the output shaft 15 is provided with a first oil hole 15b radially arranged and communicating with the first gap 15c, and the guide ring 11 is provided with a second oil hole 11b communicating the first gap 15c with the annular groove 11 a. Thus, the function of lubricating the snap ring 10 is achieved, and the planet carrier 5 is convenient to operate and move.

A second gap is formed between the guide ring 11 and the planet carrier 5, namely the guide inner hole 5d, and a third oil hole 11c for communicating the second gap, namely the guide inner hole 5d, with the first gap 15c is formed in the guide ring 11. In this way, it acts to lubricate the synchronizer and the bearings.

As shown in figure 2, the reverse gear structure of the gearbox designed by the invention utilizes the characteristic that a planetary gear system can reversely rotate to cancel a reverse gear set of a main box and a joint device thereof, power is output in a forward direction through a normally meshed gear set 1 and a first gear set 2, and then is output in a reverse direction through a sun gear 6, a planet gear 7, a gear ring 8 and an output shaft 15, at the moment, a planet carrier 5 is fixed, the planet gear 7 is equivalent to an idler gear, the gear ring 5 is driven to reversely rotate, and the gear ring 5 is jointed with the output shaft 7 to output power.

As shown in fig. 3 to 5, the planetary gear 7 is assembled on the planetary carrier 5 through the shaft 9, and the planetary carrier 5 and the output shaft 15 are connected through the spline 5b and the spline 15 a; a guide inner hole 5d is reserved at the rear end of the planet carrier 5 to form a second gap and the outer wall of the guide ring 11 to be in small-gap fit, so that the axial and radial motion guide of the planet carrier is realized. In order to prevent the planet carrier from axially shifting, a first trapezoidal groove 5c and a second trapezoidal groove 5e are respectively arranged on the planet carrier 5, an annular groove 11a is arranged on the guide ring 11, and a clamping ring 10 is placed in the annular groove 11 a; the outer diameter of the guide ring 11 is larger than the inner diameter of the clamping ring 10 and smaller than the outer diameter of the clamping ring 10, so that the front position and the rear position of the reverse gear joint of the planet carrier are positioned. The snap ring 10 is pressed in the first trapezoidal groove 5c or the second trapezoidal groove 5e by external tension, and a radial gap and an end surface gap are reserved between the snap ring and the annular groove 11 a. The front end of the planet carrier is provided with a reverse gear connecting piece 5.1, and the reverse gear connecting piece 5.1 is provided with reverse gear inner engaging teeth 5a and a gear shifting groove 5f. The two-shaft bearing cover 4 is connected to the housing 3 through bolts, and reverse gear external engagement teeth 4a are integrated on the two-shaft bearing cover 4.

When the reverse gear is engaged, the operating rod firstly pushes the gear sleeve 12 to be connected with the high-gear conical ring 13, so that the gear ring 8 is connected with the output shaft 15 through the auxiliary box high-gear synchronizer, meanwhile, the operating rod forwards pushes the reverse gear shifting groove 5f, so that the planet carrier 5 drives the planet gear assembly to slide relative to the sun gear 6 and the gear ring 8 until the reverse gear inner joint teeth 5a are connected with the 4a reverse gear outer joint teeth, and meanwhile, the clamping ring 10 slides out of the first trapezoidal groove 5c and then falls into the second trapezoidal groove 5e, so that the axial positioning of the planet carrier 5 is realized, and the gear shifting is finished (as shown in figure 5). At the moment, the planet carrier 5 and the output shaft 15 are separated and fixed on the shell 3, power is transmitted to the secondary shaft 1 through the primary gear 2 and then transmitted to the output shaft 15 through the sun gear 6, the planet gear 7, the gear ring 8, the high-gear conical ring 13 and the like, and the purpose of reverse rotation of the output shaft is achieved.

A first gap 15c is formed between part of the inner wall of the guide ring 11 and the output shaft 15; the output shaft 15 is provided with a first oil hole 15b radially arranged to communicate with the first gap 15c, and the guide ring 11 is provided with a second oil hole 11b communicating the first gap 15c with the annular groove 11 a. A second gap, i.e., the aforementioned guide inner hole 5d, is formed between the guide ring 11 and the planet carrier 5, and a third oil hole 11c for communicating the second gap, i.e., the guide inner hole 5d, with the first gap 15c is formed in the guide ring 11.

After the reverse gear is hung, the clamping ring 10 is tightly pressed in the second trapezoidal groove 5e and stays still along with the planet carrier 5, and the planet carrier 5 and the guide ring 11 rotate relatively, so that the end face of the clamping ring 10 and the end face of the clamping ring groove 11a also rotate relatively, a first oil hole 15b is added on the output shaft 15, a second oil hole 11b is added below the annular groove 11a, pressure lubricating oil of the main oil pipe 14 is guided into a clamping ring end face gap to prevent end face abrasion, and a third oil hole 11c is added to lubricate a synchronizer and a bearing.

In the description of the present invention, the terms "mounted", "connected" and "connected" should be understood broadly, and may be, for example, a fixed connection, a detachable connection, or an integral connection; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meanings of the above terms in the present invention can be understood in a specific case to those of ordinary skill in the art.

It should be understood by those skilled in the art that the above description is only a preferred embodiment of the present invention, and not intended to limit the present invention, and any modification, combination, replacement, improvement made without departing from the spirit and principle of the present invention shall fall within the protection scope of the present invention.

Claims (8)

1. The utility model provides a gearbox structure of reversing gear which characterized in that: the planetary gear is arranged on a planetary carrier through a shaft; the planet carrier can move axially and is respectively meshed with the output shaft and the shell at two limit positions; when the planet carrier is meshed with the shell, power is transmitted to the output shaft through the gear ring; a guide ring is arranged between the hole wall of the planet carrier and the outer wall of the output shaft; a snap ring is arranged between the guide ring and the planet carrier; the outer diameter of the guide ring is larger than the inner diameter of the clamping ring and smaller than the outer diameter of the clamping ring.

2. The transmission reverse gear structure according to claim 1, characterized in that: the planet carrier is provided with a reverse gear connecting piece, and the reverse gear connecting piece is connected with the operating rod; the reverse gear connecting piece can be meshed with the shell.

3. The transmission reverse gear structure according to claim 2, characterized in that: the reverse gear connecting piece is meshed with a two-shaft bearing cover arranged on the shell.

4. The transmission reverse gear structure according to claim 2 or 3, characterized in that: the outer wall of the reverse gear connecting piece is provided with a gear shifting groove, and the gear shifting groove is connected with the operating rod.

5. The transmission reverse gear structure according to claim 1, characterized in that: the inner wall of the planet carrier is at least provided with two trapezoidal grooves for accommodating the snap ring.

6. The transmission reverse gear structure according to claim 1 or 5, characterized in that: the guide ring is provided with an annular groove for accommodating the clamping ring, and the inner diameter of the annular groove is smaller than that of the clamping ring.

7. The transmission reverse gear structure according to claim 6, characterized in that: a first gap is formed between part of the inner wall of the guide ring and the output shaft; the output shaft is provided with a first oil hole which is radially arranged and communicated with the first gap, and the guide ring is provided with a second oil hole which is communicated with the first gap and the annular groove.

8. The transmission reverse gear structure according to claim 7, characterized in that: and a second gap is arranged between the guide ring and the planet carrier, and a third oil hole for communicating the second gap with the first gap is formed in the guide ring.

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