CN210135186U - Hydraulic speed reducer - Google Patents

Abstract

The utility model discloses a hydraulic speed reducer, attached vehicle gearbox installation and with vehicle gearbox's output shaft or transmission shaft parallel connection, it includes the casing, driven gear, first pivot, and integrated rotor impeller in the casing, stator impeller, second pivot and speed regulating mechanism, form the working chamber between rotor impeller and the stator impeller, the second pivot links to each other with rotor impeller, first pivot stretches into in the casing and links to each other with the second pivot through speed regulating mechanism, driven gear connects in first pivot and meshes mutually with vehicle gearbox output epaxial driving gear. The utility model discloses an integrated speed adjusting mechanism in hydraulic speed reducer's casing makes it have the speed governing function, changes hydraulic speed reducer's mounting means simultaneously, makes its and vehicle transmission parallel connection, can make hydraulic speed reducer's structure compacter, reduction in production cost.

Description

Hydraulic speed reducer

Technical Field

The utility model belongs to the technical field of the hydromechanical technique and specifically relates to an install hydraulic speed reducer between vehicle transmission and vehicle drive axle.

Background

For vehicles with high speed and heavy load, short braking distance and quick response, the requirement of people on the safety of the vehicles cannot be met only by the traditional mechanical friction type brake, and the hydraulic retarder can safely and reliably assist the braking of the vehicles to enable the vehicles to meet the safety requirement, so that the hydraulic retarder is widely applied to the vehicles.

The hydraulic speed reducer is a device which converts mechanical energy into liquid heat energy and has small abrasion, and comprises a rotor impeller, a stator impeller, a quick liquid charging and discharging mechanism and the like, wherein a working cavity is formed between the rotor impeller and the stator impeller. When the brake device works, the rotor impeller is driven by a transmission system of a vehicle, after working fluid flows into the working cavity, the rotor impeller drives the working fluid to move towards the stator impeller, the stator impeller generates reaction force on the working fluid, so that the working fluid impacts the rotor impeller to form resistance moment to the rotor impeller, the rotation of the rotor impeller is blocked, and then the deceleration braking effect on the vehicle is realized.

In the prior art, a hydrodynamic retarder usually does not have a speed regulation function, that is, the rotating speed of a rotor impeller is kept consistent with the rotating speed of a vehicle transmission shaft, for example, chinese patent CN 105757214a discloses a hydrodynamic retarder, which includes a working chamber formed by a rotor impeller and a stator impeller, an oil storage tank, a heat dissipation mechanism and a transmission shaft, a vehicle drives the rotor impeller to rotate through the transmission shaft, the rotating speed of the rotor impeller is consistent with the rotating speed of the transmission shaft, and the braking torque of the hydrodynamic retarder is generally in direct proportion to the square of the rotating speed of the rotor impeller under the condition that the braking torque coefficient, the working fluid density, the gravitational acceleration and the effective diameter of a circle are kept to be. When the vehicle climbs a slope and needs to generate a larger braking torque, the braking torque generated by the hydraulic retarder is smaller due to the fact that the vehicle speed is smaller, so that the deceleration braking effect of the hydraulic retarder on the vehicle is weakened, and the actual use requirement cannot be met; or when the vehicle runs at a high speed, the idle running loss of the hydraulic retarder is correspondingly increased due to the increase of the rotating speed of the rotor impeller.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome prior art's defect, provide a hydraulic decelerator with speed governing function.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a hydraulic speed reducer, the attached formula of hydraulic speed reducer is installed on the vehicle gearbox to with output shaft or the transmission shaft parallel connection of vehicle gearbox, hydraulic speed reducer includes casing, driven gear, first pivot, and is integrated rotor wheel, stator impeller, second pivot and the speed adjusting mechanism in the casing, form the working chamber between rotor wheel and the stator impeller, the second pivot with rotor wheel links to each other, the output shaft parallel arrangement of first pivot and vehicle gearbox, just first pivot stretches into in the casing and links to each other with the second pivot through the speed adjusting mechanism, driven gear hub connection is in the part outside the casing at first pivot, just the driving gear meshing that sets up on driven gear and the output shaft of vehicle gearbox is connected.

Preferably, the speed adjusting mechanism includes a first speed changing gear and a second speed changing gear, the first rotating shaft is coupled to the first speed changing gear, the second rotating shaft is coupled to the second speed changing gear, and the first speed changing gear is meshed with the second speed changing gear.

Preferably, the speed adjusting mechanism includes a first speed changing gear, a second speed changing gear, a third speed changing gear, a fourth speed changing gear and a third rotating shaft, the third rotating shaft is coupled to the third speed changing gear and the fourth speed changing gear, the first rotating shaft is coupled to the first speed changing gear, the first speed changing gear is meshed with the third speed changing gear, the second rotating shaft is coupled to the second speed changing gear, and the second speed changing gear is meshed with the fourth speed changing gear.

Preferably, the speed adjusting mechanism includes a first speed changing gear, a second speed changing gear, a third speed changing gear, a fourth speed changing gear and a clutch, the first rotating shaft is coupled to the first speed changing gear and the third speed changing gear, the second rotating shaft is coupled to the second speed changing gear and the fourth speed changing gear, the first speed changing gear is meshed with the second speed changing gear, the third speed changing gear is meshed with the fourth speed changing gear, the clutch is arranged on the second rotating shaft, and the clutch is combined with any one of the second speed changing gear and the fourth speed changing gear, or the clutch is separated from both the second speed changing gear and the fourth speed changing gear.

Preferably, the speed ratio of the rotor impeller to the first rotating shaft is 0.25-4.

Preferably, a rotation speed sensor for measuring the rotation speed is arranged on the first rotating shaft and/or the second rotating shaft.

Preferably, a rotation speed sensor for measuring rotation speed is arranged on the third rotating shaft.

Preferably, the working fluid circulating device further comprises a liquid storage tank for storing the working fluid and a heat dissipation mechanism for dissipating heat of the working fluid, and a circulating passage for recycling the working fluid is formed among the working cavity, the liquid storage tank and the heat dissipation mechanism.

Preferably, the working cavity is provided with a working liquid inlet and a working liquid outlet, the working liquid inlet is communicated with the liquid storage tank, the working liquid outlet is communicated with the heat dissipation mechanism, and the heat dissipation mechanism is communicated with the liquid storage tank.

Preferably, the liquid storage tank is provided with an opening for compressed air to enter or discharge, and the opening is provided with a control valve for controlling compressed air to enter or discharge.

The utility model has the advantages that:

(1) the speed regulating mechanism is integrated in the shell of the hydraulic speed reducing device, so that the hydraulic speed reducing device has a speed regulating function, the rotating speed of the rotor impeller is regulated by the speed regulating mechanism, on one hand, the braking torque of the hydraulic speed reducing device can be effectively changed, the braking performance of the hydraulic speed reducing device is changed, the hydraulic speed reducing device can better perform speed reduction braking on a vehicle, and on the other hand, the idling loss of the hydraulic speed reducing device can be effectively reduced.

(2) The hydraulic speed reducer is attached to the vehicle gearbox by changing the installation mode of the hydraulic speed reducer and is connected with the output shaft or the transmission shaft of the vehicle gearbox in parallel, so that the structure of the hydraulic speed reducer is more compact, the axial installation size is reduced, and the installation cost is reduced.

Drawings

Fig. 1 is a schematic view of an installation position of a hydraulic speed reducer according to the present invention;

FIG. 2 is a schematic diagram of the structure of the present invention;

fig. 3 is a schematic cross-sectional view of a hydrodynamic retarder device according to an embodiment of the present invention;

fig. 4 is a schematic structural diagram of an embodiment of the present invention;

FIG. 5 is a schematic structural diagram of a second embodiment of the present invention;

fig. 6 is a schematic diagram of a third structure according to an embodiment of the present invention.

Reference numerals: a. the hydraulic speed reducer comprises a hydraulic speed reducer, a vehicle gearbox, a vehicle drive axle, a transmission shaft, a shell, a working cavity, a rotating speed sensor, a driven gear, a rotor impeller, a stator impeller, a rotor impeller, a stator impeller, a rotor, a working cavity, a working speed sensor, a driven gear, a working cavity, a working.

Detailed Description

The technical solution of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings of the present invention.

As shown in fig. 1, the utility model discloses a hydraulic speed reducer a, attached vehicle transmission b installs, and with vehicle transmission b's output shaft or transmission shaft d parallel connection, also hydraulic speed reducer a installs in an organic whole through connecting piece or other modes and vehicle transmission b, hydraulic speed reducer a is connected through the driving gear meshing that sets up on driven gear 20 and the vehicle transmission b output shaft simultaneously, the mode that adopts parallel connection can make hydraulic speed reducer's structure compacter, reduce axial installation size, reduce installation cost.

Referring to fig. 2 and 3, the hydraulic speed reducer disclosed in the present invention includes a housing 10, a driven gear 20, a first rotating shaft 30, a rotor impeller 40, a stator impeller 50, a second rotating shaft 60, and a speed adjusting mechanism 70, wherein the rotor impeller 40, the stator impeller 50, the second rotating shaft 60, and the speed adjusting mechanism 70 are integrated in the housing 10, the rotor impeller 40 is mounted on the second rotating shaft 60, a working chamber 11 is formed between the rotor impeller 40 and the stator impeller 50, and the working chamber 11 can be filled with working fluid such as hydraulic oil; the second rotating shaft 60 is connected with the rotor impeller 40, and the rotor impeller 40 rotates along with the rotation of the second rotating shaft 60; the first rotating shaft 30 is arranged in parallel with an output shaft of a vehicle gearbox, and the first rotating shaft 30 extends into the shell 10 and is connected with the second rotating shaft 60 through a speed regulating mechanism 70; the driven gear 20 is axially connected to a portion of the first rotating shaft 30 located outside the casing 10, and the driven gear 20 is engaged with a driving gear provided on an output shaft of a transmission of a vehicle.

When the hydraulic speed reducer works, the output shaft of the vehicle gearbox drives the driven gear 20 to rotate through the driving gear, the driven gear 20 further drives the first rotating shaft 30 to rotate, the first rotating shaft 30 adjusts the rotating speed of the second rotating shaft 60 through the speed adjusting mechanism 70, so that the rotating speed of the rotor impeller 40 is further adjusted to be higher or lower than that of the transmission shaft d, the rotor impeller 40 drives working fluid to move towards the stator impeller 50, the stator impeller 50 generates reaction force on the working fluid, the working fluid impacts the rotor impeller 40 to form resistance torque to the rotor impeller 40, the rotation of the rotor impeller 40 is blocked, the braking torque of the hydraulic speed reducer is finally changed, the braking performance of the hydraulic speed reducer is changed, and the hydraulic speed reducer can better perform speed reduction braking on a vehicle.

In the embodiment, the speed ratio of the rotor impeller to the first rotating shaft is preferably 0.25-4, so that the transmission efficiency can be effectively improved.

The structure of the governor mechanism 70 in the hydrodynamic retarder will be described in detail below with three embodiments, but it is needless to say that the present invention is not limited to the above three governor mechanisms 70, and the governor mechanism 70 may be provided according to actual requirements, such as the number of transmission gears required and whether or not a clutch is required according to actual speed requirements.

Example one

Referring to fig. 3 and 4, the governor mechanism 70 includes a first transmission gear 71 and a second transmission gear 72, wherein the first shaft 30 is coupled to the first transmission gear 71, the second shaft 60 is coupled to the second transmission gear 72, and the first transmission gear 71 is meshed with the second transmission gear 72.

In practical implementation, the first rotating shaft 30 drives the first speed-changing gear 71 to rotate, and the first speed-changing gear 71 further drives the second speed-changing gear 72 engaged with the first speed-changing gear to rotate; the second speed-changing gear 72 drives the second rotating shaft 60 to rotate, so as to drive the rotor impeller 40 to rotate, so that the rotating speed of the rotor impeller 40 is changed under the action of the first speed-changing gear 71 and the second speed-changing gear 72, and the braking torque of the hydraulic speed reducer is changed.

In the present embodiment, the first transmission gear 71 may be mounted on the first rotating shaft 30 by interference fit, or may be mounted on the first rotating shaft 30 by other methods, such as key connection. Similarly, the second speed-changing gear 72 can be mounted on the second rotating shaft 60 by interference fit, or can be mounted on the first rotating shaft 30 by other methods, such as key connection.

Example two

As shown in fig. 5, the governor mechanism 70 includes a first transmission gear 71, a second transmission gear 72, a third transmission gear 73, a fourth transmission gear 74 and a third rotating shaft 75, wherein the third rotating shaft 75 is coupled to the third transmission gear 73 and the fourth transmission gear 74, the first rotating shaft 30 is coupled to the first transmission gear 71, the first transmission gear 71 is in meshed connection with the third transmission gear 73, the second rotating shaft 60 is coupled to the second transmission gear 72, and the second transmission gear 72 is in meshed connection with the fourth transmission gear 74.

In practical implementation, the first rotating shaft 30 drives the first speed-changing gear 71 to rotate, and the first speed-changing gear 71 further drives the third speed-changing gear 73 engaged with the first speed-changing gear to rotate; the second speed changing gear 62 drives the third rotating shaft 75 to rotate, and further drives the fourth speed changing gear 74 to rotate; the fourth transmission gear 74 rotates to further drive the second transmission gear 72 engaged therewith to rotate, and the second transmission gear 72 drives the second rotating shaft 60 to rotate, so as to drive the rotor impeller 40 to rotate, so that the rotating speed of the rotor impeller 40 is changed under the action of the first transmission gear 71, the second transmission gear 72, the third transmission gear 73 and the fourth transmission gear 74, and the braking torque of the hydraulic speed reducer is changed.

In the present embodiment, the first transmission gear 71 may be mounted on the first rotating shaft 30 by interference fit, or may be mounted on the first rotating shaft 30 by other methods, such as key connection. Similarly, the second speed-changing gear 72, the third speed-changing gear 73 and the fourth speed-changing gear 74 can be disposed on the corresponding transmission shafts in an interference fit manner, or can be disposed on the corresponding transmission shafts in other manners, such as a key connection manner.

EXAMPLE III

As shown in fig. 6, the governor mechanism 70 includes a first transmission gear 71, a second transmission gear 72, a third transmission gear 73, a fourth transmission gear 74 and a clutch 76, wherein the first shaft 30 is coupled to the first transmission gear 71 and the third transmission gear 73, the second shaft 60 is coupled to the second transmission gear 72 and the fourth transmission gear 74, the first transmission gear 71 is meshed with the second transmission gear 72, and the third transmission gear 73 is meshed with the fourth transmission gear 74; further, a clutch 76 is provided on the second rotary shaft 60 between the second speed change gear 72 and the fourth speed change gear 74, which may be combined with any one of the second speed change gear 62 and the fourth speed change gear 64, or may be separated from both the second speed change gear 62 and the fourth speed change gear 64. The rotor wheel 40 is caused to have different rotational speeds by engaging the clutch 76 with the second speed gear 72 or the fourth speed gear 74.

In particular implementation, when the clutch 76 is disengaged from either the second ratio gear 72 or the fourth ratio gear 74, the hydrodynamic retarder is not operated;

when the clutch 76 is engaged with the second speed change gear 72, the first rotating shaft 30 drives the first speed change gear 71 to rotate, and the first speed change gear 71 further drives the second speed change gear 72 engaged therewith to rotate; the second speed changing gear 72 drives the second rotating shaft 60 to rotate, so as to drive the rotor impeller 40 to rotate, so that the rotating speed of the rotor impeller 40 is changed under the action of the first speed changing gear 71 and the second speed changing gear 72, and further the braking torque of the hydraulic speed reducing device is changed;

when the clutch 76 is engaged with the fourth speed change gear 74, the first rotary shaft 30 drives the third speed change gear 73 to rotate, and the third speed change gear 73 further drives the fourth speed change gear 74 engaged therewith to rotate; the fourth speed-changing gear 74 drives the second rotating shaft 60 to rotate, so as to drive the rotor impeller 40 to rotate, so that the rotating speed of the rotor impeller 40 is changed under the action of the third speed-changing gear 73 and the fourth speed-changing gear 74, and the braking torque of the hydraulic speed reducer is changed.

In this embodiment, the first speed-changing gear 71, the second speed-changing gear 72, the third speed-changing gear 73 and the fourth speed-changing gear 74 can be mounted on the corresponding rotating shafts in an interference fit manner, or can be mounted on the corresponding rotating shafts in other manners, such as a key connection manner.

Compared with the prior art, the utility model discloses an aspect makes hydraulic speed reducer have the speed governing function through integrated speed adjusting mechanism 70 in hydraulic speed reducer, adjust the rotational speed of rotor impeller 40 through speed adjusting mechanism 70, on the one hand when the vehicle is in states such as climbing, accessible speed adjusting mechanism 70 makes the rotational speed of rotor impeller 30 improve, and then change hydraulic speed reducer's braking torque, change hydraulic speed reducer's brake performance, make hydraulic speed reducer can be better carry out speed reduction braking to the vehicle, on the other hand when the vehicle is in states such as high-speed traveling, the rotational speed that accessible speed adjusting mechanism 70 made rotor impeller 30 reduces, and then reduce hydraulic speed reducer's idle running loss; meanwhile, the installation mode of the hydraulic speed reducer is changed, the hydraulic speed reducer is attached to a vehicle gearbox and is connected with the vehicle gearbox in parallel, the structure of the hydraulic speed reducer is more compact, the axial installation size is reduced, and the installation cost is reduced.

As shown in fig. 2, the hydraulic retarder further includes a rotation speed sensor 12 for measuring a rotation speed, which may be disposed on the first rotating shaft 30 for measuring a rotation speed of the first rotating shaft 30, may be disposed on the second rotating shaft 60 for measuring a rotation speed of the second rotating shaft 60, may be disposed on the third rotating shaft 65 for measuring a rotation speed of the third rotating shaft 65, and of course, the rotation speed sensor 12 may be disposed on each of the first rotating shaft 20, the second rotating shaft 50, and the third rotating shaft 65. When the hydraulic reduction device has a plurality of rotating shafts, the rotating speed sensor 12 may be provided on each rotating shaft, or may be set according to actual requirements, such as on a speed change gear, and the like.

Further, the hydraulic reduction gear further includes a reservoir 80 for storing the working fluid and a heat dissipation mechanism 90 for dissipating heat from the working fluid, and a circulation path for circulating the working fluid is formed among the working chamber 11, the reservoir 80, and the heat dissipation mechanism 90. Specifically, the working chamber 11 has a working fluid inlet and a working fluid outlet, wherein the working fluid inlet is communicated with the liquid storage tank 70, the working fluid outlet is communicated with the heat dissipation mechanism 80, the heat dissipation mechanism 80 is further communicated with the liquid storage tank 70, in the implementation process, the working fluid in the liquid storage tank 70 enters the working chamber 11 from the working fluid inlet, the rotor impeller 30 drives the working fluid to move so as to convert the mechanical energy into heat energy, the working fluid further enters the heat dissipation mechanism 80 from the working fluid outlet, and the heat dissipation mechanism 80 dissipates the heat of the working fluid and then finally inputs the working fluid into the liquid storage tank 70, so that the working fluid can be recycled. In this embodiment, the heat dissipation mechanism is preferably a heat exchanger.

Further, the liquid storage tank 80 is provided with an opening for the inlet or outlet of compressed air, and the opening is provided with a control valve 100 for controlling the inlet or outlet of compressed air.

The technical contents and features of the present invention have been disclosed as above, however, those skilled in the art can still make various substitutions and modifications based on the teaching and disclosure of the present invention without departing from the spirit of the present invention, therefore, the protection scope of the present invention should not be limited to the contents disclosed in the embodiments, but should include various substitutions and modifications without departing from the present invention, and should be covered by the claims of the present patent application.

Claims (10)

1. A hydraulic retarding device, characterized in that it is attachingly mounted on a vehicle gearbox, and is connected in parallel with the output shaft or transmission shaft of the vehicle gearbox, the hydraulic speed reducer comprises a shell, a driven gear and a first rotating shaft, a rotor impeller, a stator impeller, a second rotating shaft and a speed regulating mechanism which are integrated in the shell and used for regulating the rotating speed of the rotor impeller, a working cavity is formed between the rotor impeller and the stator impeller, the second rotating shaft is connected with the rotor impeller, the first rotating shaft is arranged in parallel with an output shaft of a vehicle gearbox, the first rotating shaft extends into the shell and is connected with the second rotating shaft through the speed regulating mechanism, the driven gear is connected with the part of the first rotating shaft, which is positioned outside the shell, and the driven gear is meshed with a driving gear arranged on an output shaft of a vehicle gearbox.

2. A hydrodynamic retarder device as claimed in claim 1, wherein the governor mechanism includes a first speed change gear and a second speed change gear, the first shaft is coupled to the first speed change gear, the second shaft is coupled to the second speed change gear, and the first speed change gear is in mesh with the second speed change gear.

3. A hydrodynamic retarder device as claimed in claim 1, wherein the governor mechanism includes a first speed change gear, a second speed change gear, a third speed change gear, a fourth speed change gear, and a third shaft, the third shaft being journalled to the third speed change gear and the fourth speed change gear, the first shaft being journalled to the first speed change gear and the first speed change gear being in mesh with the third speed change gear, the second shaft being journalled to the second speed change gear and the second speed change gear being in mesh with the fourth speed change gear.

4. A hydrodynamic retarder device according to claim 1, wherein the governor mechanism includes a first speed change gear, a second speed change gear, a third speed change gear, a fourth speed change gear, and a clutch, the first shaft is coupled to the first speed change gear and the third speed change gear, the second shaft is coupled to the second speed change gear and the fourth speed change gear, and the first speed change gear is engaged with the second speed change gear, the third speed change gear is engaged with the fourth speed change gear, the clutch is provided on the second shaft, and the clutch is coupled to any one of the second speed change gear and the fourth speed change gear, or the clutch is decoupled from both the second speed change gear and the fourth speed change gear.

5. A hydrodynamic retarder device as claimed in claim 1, wherein the rotor impeller has a speed ratio to the first shaft of 0.25-4.

6. A hydrodynamic retarder device according to claim 1, characterized in that the first and/or second shaft is provided with a rotation speed sensor for measuring the rotation speed.

7. A hydrodynamic retarder device as claimed in claim 3, wherein the third shaft is provided with a speed sensor for measuring the speed of rotation.

8. A hydrodynamic retarder device as claimed in claim 1, further comprising a reservoir for storing the working fluid and a heat dissipating mechanism for dissipating heat from the working fluid, wherein the working chamber, the reservoir and the heat dissipating mechanism define a circulation path for circulating the working fluid.

9. A hydrodynamic retarder device as defined in claim 8 wherein the working chamber has a working fluid inlet and a working fluid outlet, the working fluid inlet being in communication with the reservoir, the working fluid outlet being in communication with the heat sink mechanism, the heat sink mechanism being in communication with the reservoir.

10. A hydrodynamic retarder device as claimed in claim 8, wherein the reservoir is provided with an opening for the admission or discharge of compressed air, the opening being provided with a control valve for controlling admission or discharge of compressed air.

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