阅读说明：本技术 一种制动器的螺旋滚道加压机构 (Spiral raceway pressurizing mechanism of brake ) 是由 任毅如 刘守河 宁克焱 向剑辉 金其多 胡铮 杨玲玲 于 2021-08-30 设计创作，主要内容包括：本发明公开了一种制动器的螺旋滚道加压机构,包括支撑体、转动盘、滚珠、循环管和推力轴承,所述转动盘安装于所述支撑体内侧,所述推力轴承设置于所述转动盘与动摩擦片之间,所述支撑体与所述转动盘之间设置有圆柱螺线形的内滚道,所述循环管固定于所述支撑体的外表面,所述循环管为中空的结构,其内部的中空区域形成外滚道,所述外滚道与所述内滚道连通形成闭合的循环滚道,多个所述滚珠逐个抵接的排布于所述循环滚道内。本发明提供的制动器的螺旋滚道加压机构不容易发生支撑体变形导致的卡死现象。(The invention discloses a spiral raceway pressurizing mechanism of a brake, which comprises a support body, a rotating disc, rolling balls, a circulating pipe and a thrust bearing, wherein the rotating disc is arranged on the inner side of the support body, the thrust bearing is arranged between the rotating disc and a dynamic friction plate, a cylindrical spiral inner raceway is arranged between the support body and the rotating disc, the circulating pipe is fixed on the outer surface of the support body, the circulating pipe is of a hollow structure, an outer raceway is formed in a hollow area inside the circulating pipe, the outer raceway is communicated with the inner raceway to form a closed circulating raceway, and a plurality of rolling balls are abutted one by one and arranged in the circulating raceway. The spiral raceway pressurizing mechanism of the brake provided by the invention is not easy to generate the phenomenon of blocking caused by deformation of the support body.)

1. The utility model provides a spiral raceway loading mechanism of stopper which characterized in that, includes supporter, rolling disc, ball, circulating pipe and thrust bearing, the rolling disc install in the supporter is inboard, thrust bearing set up in between rolling disc and the dynamic friction piece, the supporter with be provided with the interior raceway of cylinder spiral line shape between the rolling disc, the circulating pipe is fixed in the surface of supporter, the circulating pipe is hollow structure, and its inside hollow region forms outer raceway, outer raceway with interior raceway intercommunication forms closed circulation raceway, and is a plurality of the arrangement of ball butt one by one in the circulation raceway.

2. The spiral raceway pressurizing mechanism for a brake according to claim 1, wherein central axes of the support body, the rotary disk, and the thrust bearing are located on a same straight line.

3. The spiral raceway pressurizing mechanism for a brake according to claim 1, wherein the support body includes an inner surface located inside and an outer surface located opposite to the inner surface, the inner surface has a first spiral groove recessed toward the outer surface, the outer surface has a mounting groove recessed toward the inner surface, the support body further has two circulation through holes formed therethrough, one of the circulation through holes communicates with a head end of the first spiral groove, the other circulation through hole communicates with a tail end of the first spiral groove, the circulation pipe is fixed in the mounting groove, and openings at both ends of the circulation pipe communicate with the two circulation through holes, respectively.

4. A spiral raceway pressurization mechanism for a brake according to claim 3, characterized in that a horizontal projection of said first spiral groove is a major arc.

5. The spiral raceway pressurizing mechanism of the brake as claimed in claim 4, wherein a second spiral groove is formed by the rotation disc being recessed away from the support body, the second spiral groove and the first spiral groove cooperate to form the inner raceway, and two sealing rings are further disposed between the rotation disc and the support body, the two sealing rings being disposed on opposite sides of the second spiral groove.

6. The spiral raceway pressurizing mechanism for a brake of claim 5, wherein the circulation pipe includes two first portions disposed opposite to each other and a second portion connecting the two first portions, the first portions being disposed opposite to the circulation through holes, and the first portions and the second portions being smoothly transited.

7. The spiral raceway pressurizing mechanism of the brake according to claim 1, wherein the thrust bearing includes two parallel spaced bearing races and a retainer interposed between the two bearing races, one of the bearing races is connected to the rotating disc, the other of the bearing races is connected to the dynamic friction plate, the retainer is formed with a plurality of roller grooves in a penetrating manner, the roller grooves are provided with rollers, the rollers are interposed between the two bearing races, and the roller grooves limit the rollers.

8. The spiral raceway pressurization mechanism of the brake according to claim 7, wherein said rollers are placed in a radial direction of said cage, and a plurality of said rollers are distributed in an annular array along a central axis of said cage.

9. The brake spiral race pressurization mechanism according to claim 7, characterized in that the roller is a cylindrical roller.

[ technical field ] A method for producing a semiconductor device

The invention relates to the technical field of vehicle brakes, in particular to a spiral raceway pressurizing mechanism of a brake.

[ background of the invention ]

Vehicles such as tanks, heavy vehicles, tracked vehicles, armored vehicles and high-speed rails all have the characteristic of large weight, and some vehicles are also required to have higher vehicle speed and higher maneuverability, so that the structural design and the manufacture of the vehicles face huge adjustment. The brake is a core component for realizing acceleration and deceleration and various maneuvering actions of the vehicle and plays a key role in the overall performance of the vehicle.

For a crawler vehicle, a multi-disc type marble pressurizing braking structure is generally adopted, a ball groove is formed between a support body and a rotating disc, balls are arranged in the ball groove, the balls are arranged along the same horizontal plane, in the braking and maneuvering process, the temperature of the support body is increased due to higher braking load and vehicle speed, and the phenomenon that the balls are blocked in the ball groove due to the fact that the ball groove is easy to deform is caused. Therefore, it is necessary to provide a spiral raceway pressing mechanism of a brake to solve the above problems.

[ summary of the invention ]

The invention provides a spiral raceway pressurizing mechanism of a brake, which has high force transmission efficiency and force boosting effect and has smaller deformation of a support body.

In order to achieve the purpose, the technical scheme of the invention is as follows:

the utility model provides a spiral raceway loading mechanism of stopper, includes supporter, rolling disc, ball, circulating pipe and thrust bearing, the rolling disc install in the supporter is inboard, thrust bearing set up in between rolling disc and the dynamic friction piece, the supporter with be provided with the interior raceway of cylinder spiral line shape between the rolling disc, the circulating pipe is fixed in the surface of supporter, the circulating pipe is hollow structure, and its inside hollow region forms outer raceway, outer raceway with interior raceway intercommunication forms closed circulation raceway, and is a plurality of the row of ball butt one by one arrange in the circulation raceway.

Preferably, the central axes of the support body, the rotating disc and the thrust bearing are located on the same straight line.

Preferably, the support body comprises an inner surface located on the inner side and an outer surface arranged opposite to the inner surface, the inner surface is recessed with a first spiral groove towards the direction close to the outer surface, the outer surface is recessed towards the direction close to the inner surface to form a mounting groove, the support body is further provided with two circulating through holes in a penetrating manner, one of the circulating through holes is communicated with the head end of the first spiral groove, the other circulating through hole is communicated with the tail end of the first spiral groove, the circulating pipe is fixed in the mounting groove, and openings at two ends of the circulating pipe are respectively communicated with the two circulating through holes.

Preferably, the horizontal projection of the first spiral groove is a major arc.

Preferably, the rotating disc is sunken to keeping away from the supporter direction and is formed with the second helicla flute, the second helicla flute with the cooperation of first helicla flute forms interior raceway, the rotating disc with still be provided with the sealing ring between the supporter, the quantity of sealing ring is two, two the sealing ring set up respectively in the relative both sides of second helicla flute.

Preferably, the circulation pipe comprises two first parts which are oppositely arranged and a second part which is connected with the two first parts, the first parts are arranged opposite to the circulation through hole, and the first parts and the second parts are smoothly transited.

Preferably, thrust bearing includes that two parallel spaced bearing races and clamp locate two retainer between the bearing race, one of them bearing race with the rolling disc is connected, another bearing race is connected with the dynamic friction piece, run through on the retainer and form a plurality of roller grooves, the roller is installed to the roller inslot, the roller clamp is located two between the bearing race, the roller groove is right the roller forms spacingly.

Preferably, the rollers are arranged along the radial direction of the retainer, and the rollers are distributed in an annular array along the central axis of the retainer.

Preferably, the rollers are cylindrical rollers.

Compared with the prior art, the spiral roller path is provided with the cylindrical spiral roller path, the rotating disc is driven by the spiral motion of the roller to generate axial displacement, and meanwhile, the actuating torque is converted into actuating pressure, so that the force transmission efficiency and the force boosting effect are higher. Moreover, compared with the eccentric loading of the traditional marble pressurizing mechanism, the spiral loading mode is adopted, the contact area with the supporting body is increased, the deformation of the supporting body is smaller, and the blocking phenomenon caused by the deformation of the supporting body is not easy to occur.

[ description of the drawings ]

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments are briefly introduced below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without inventive efforts, wherein:

fig. 1 is a schematic structural diagram of a spiral raceway pressurizing mechanism of a brake provided by the invention;

FIG. 2 is an exploded view of a helical raceway pressing mechanism of the brake shown in FIG. one;

FIG. 3 is an enlarged view of area A shown in FIG. 2;

FIG. 4 is a schematic view of another angle of the support body shown in FIG. 2;

FIG. 5 is a schematic view of the connection structure of the roller and the rotary disk;

FIG. 6 is a sectional view taken along line B-B of the spiral raceway pressing mechanism of the brake shown in FIG. 1;

FIG. 7 is a partial cross-sectional view of a portion of a circulation tube of a spiral raceway pressurization mechanism of a brake;

fig. 8 is an exploded view of the thrust bearing.

[ detailed description ] embodiments

The following description of the present invention is provided to enable those skilled in the art to better understand the technical solutions in the embodiments of the present invention and to make the above objects, features and advantages of the present invention more comprehensible.

Referring to fig. 1 to 8, the present invention provides a spiral raceway pressurizing mechanism 100 for a brake, including a support body 10, a circulation pipe 20, balls 30, a rotary disk 40, and a thrust bearing 50. The rotary disk 40 and the thrust bearing 50 are both installed inside the support body 10, and the thrust bearing 50 is connected to the rotary disk 40. The central axes of the support body 10, the rotating disk 40 and the thrust bearing 50 are located on the same straight line.

A cylindrical and spiral inner raceway is arranged between the rotating disc 40 and the support body 10, the circulating pipe 20 is fixed on the outer side of the support body 10, the circulating pipe 20 is of a hollow structure, an outer raceway is surrounded in a hollow area, the outer raceway is communicated with the inner raceway to form a closed circulating raceway, and a plurality of balls 30 are arranged in the circulating raceway in a one-by-one abutting mode.

The support body 10 is an annular structure, and an accommodating space is enclosed inside the support body. Specifically, the support body 10 includes an inner surface 11 located in the accommodating space and an outer surface 12 disposed opposite to the inner surface 11, and the inner surface 11 is recessed with a first spiral groove 13 toward the outer surface 12. The central axis of the first spiral groove 13 is located on the same straight line as the central axis of the support body 10, and the rotation direction and the lead of the first spiral groove 13 may be set according to actual needs, which is not limited in this embodiment. The first spiral groove 13 is in the shape of a cylindrical spiral, so that the head end and the tail end of the first spiral groove 13 are located at different horizontal heights, in this embodiment, the horizontal projection of the first spiral groove 13 is a major arc, that is, the first spiral groove 13 is not fully rotated.

The outer surface 12 is recessed toward the inner surface 11 to form a mounting groove 14, and the support body 10 is further provided with two circulating through holes 15, wherein one of the circulating through holes 15 is communicated with the head end of the first spiral groove 13, and the other circulating through hole 15 is communicated with the tail end of the first spiral groove 13.

The circulation pipe 20 is fixed in the installation groove 14, and openings at two ends of the circulation pipe 20 are respectively communicated with the two circulation through holes 15. The circulation pipe 15 comprises two first portions 151 arranged oppositely and a second portion 152 connecting the two first portions 151, the first portions 151 are arranged opposite to the circulation through holes 15, the penetrating direction of the circulation through holes 15 is the radial direction of the support body 10, the two first portions 151 play a role in transition between the second portions 152 and the circulation through holes 15, the first portions 151 and the second portions 152 smoothly transition, and the second portions 152 integrally extend in a straight line, so that the balls 30 are prevented from being stuck in the circulation pipe 30.

It will be appreciated that the circulation pipe 20 is inclined with respect to the horizontal plane due to the difference in height between the head and tail ends of the circulation pipe 20.

The balls 30 are interposed between the support body 10 and the rotating disk 40, and when the rotating disk 40 rotates, the balls 30 are driven to move in the circulating raceway, and because the inner raceway is helical, the balls 30 generate an axial driving force on the rotating disk 40, and the balls 30 in the inner raceway always form a tangential direction of a circular helix under the action of the rotating disk 40, so that the axial acting force of the balls 30 on the rotating disk 30 is always kept in one direction. The rotation direction of the balls 30 in the outer raceway is opposite to that of the balls in the inner raceway, but the balls 30 in the outer raceway are in direct contact with the circulating pipe 20 and are not in direct contact with the rotating disc 30, so that the acting force of the balls 30 in the outer raceway is directly borne by the circulating pipe 20, and the moving direction of the rotating disc 40 can be ensured to be always in a single direction.

The rotating disc 40 is driven to generate axial displacement through the spiral motion of the roller 30, and meanwhile, the actuating torque is converted into the actuating pressure, so that the force transmission efficiency and the force increasing effect are high. Moreover, compared with the eccentric loading of the traditional marble pressurizing mechanism, the spiral loading mode is adopted, the contact area between the support body 10 and the spiral loading mechanism is increased, the deformation of the support body 10 is smaller, and the blocking phenomenon caused by the deformation of the support body 10 is not easy to occur.

The central axis of the rotating disc 40 and the central axis of the supporting body 10 are located on the same straight line, a second spiral groove 41 is formed on the outer surface of the rotating disc 40 in a concave manner towards the direction far away from the supporting body 10, the second spiral groove 41 is matched with the first spiral groove 13 in shape, and the second spiral groove 41 and the first spiral groove 13 are matched to form the inner raceway in a surrounding manner.

Further, two sealing rings 60 are further disposed between the rotating disc 40 and the support body 10, and the two sealing rings 60 are disposed on two opposite sides of the second spiral groove 41. In this embodiment, it is direct that the both ends of rolling disc 40 are sunken to set up ladder groove 42, sealing ring 60 install in the ladder inslot, sealing ring 60's internal surface with rolling disc 40 in close contact with, sealing ring 60's surface with the internal surface in close contact with of supporter 10 can improve by a wide margin the driving disc 40 with the leakproofness that supporter 10 is connected avoids the dust to get into the circulation raceway influences the normal operating of ball 30.

The thrust bearing 50 is arranged between the dynamic friction plate and the rotating disc 40, the dynamic friction plate can only move axially and can not rotate, and the thrust bearing 50 is additionally arranged between the dynamic friction plate and the rotating disc 40 and is mainly used for transmitting axial force because the rotating disc 40 can move axially and simultaneously rotates along with the rotation, if the rotating disc is in direct contact with a pressure plate, the rotating disc can rub against the pressure plate when rotating, and the resistance is increased.

Thrust bearing 50 includes two parallel spaced bearing race 51 and presss from both sides and locates two cage 52 between the bearing race 51, run through on the cage 52 and form a plurality of roller grooves 520, install roller 53 in the roller groove 520, roller 53 presss from both sides and locates two between the bearing race 51, roller 53 is cylindrical roller, roller groove 520 is right roller 53 forms spacingly, makes roller 53 can only be in rotate around its self axis direction in the roller groove 520. The plurality of rollers 53 are disposed along a radial direction of the cage 52, and the plurality of rollers 53 are distributed in an annular array along a central axis of the cage 52.

The actuating structure is connected with the rotating disc 40, the driving force is input by the actuating structure to drive the rotating disc 40 to rotate, and due to the spiral raceway structure, the balls 30 can drive the rotating disc 40 to generate axial displacement in the rotating process. One bearing race 51 is connected with the rolling disc 40, and another bearing race 51 is connected with the dynamic friction piece, the rolling disc 40 can drive the bearing race 51 who is connected rather than rotate and produce axial displacement simultaneously at the motion in-process, because thrust bearing 50 formula structure as an organic whole, another thrust bearing 51 also can produce axial displacement, and then drives the dynamic friction piece and move to being close to the dynamic friction piece direction, and extrudees the dynamic friction piece forms braking effect. It will be appreciated that axial forces are transmitted between the two bearing races 51 of the thrust bearing 50 via the rollers 53, and that rolling friction is formed between the bearing races 51 and the rollers 53, which reduces drag.

Compared with the prior art, the spiral roller path is provided with the cylindrical spiral roller path, the rotating disc is driven by the spiral motion of the roller to generate axial displacement, and meanwhile, the actuating torque is converted into actuating pressure, so that the force transmission efficiency and the force boosting effect are higher. Moreover, compared with the eccentric loading of the traditional marble pressurizing mechanism, the spiral loading mode is adopted, the contact area with the supporting body is increased, the deformation of the supporting body is smaller, and the blocking phenomenon caused by the deformation of the supporting body is not easy to occur.

The embodiments of the present invention have been described in detail, but the present invention is not limited to the described embodiments. Various changes, modifications, substitutions and alterations to these embodiments will occur to those skilled in the art without departing from the spirit and scope of the present invention.