CN111071278B

CN111071278B - Method and structure for adjusting vertical rigidity of primary suspension device

Info

Publication number: CN111071278B
Application number: CN202010036764.1A
Authority: CN
Inventors: 兰加标; 李刚; 孙海燕; 谭方; 冯万盛
Original assignee: Zhuzhou Times Ruiwei Damping Equipment Co Ltd
Current assignee: Zhuzhou Times Ruiwei damping equipment Co., Ltd
Priority date: 2020-01-14
Filing date: 2020-01-14
Publication date: 2021-01-22
Anticipated expiration: 2040-01-14
Also published as: CN111071278A

Abstract

The primary suspension device comprises a base, a conical spring and a limiting stop, wherein the conical spring comprises a rubber body and a mandrel, the lower end of a bogie is provided with a stop hole, the upper end of the mandrel is arranged in the stop hole of the bogie, and cavities are formed in the rubber body and the mandrel; the base is internally provided with two conical springs side by side along the longitudinal direction, a cavity of each conical spring is internally provided with a limiting stop which comprises a stop seat and a stop rod, and the stop rods are integrally formed above the stop seat; be equipped with the axle box seat on the axle box, the pedestal mounting produces relative movement in the axle box seat in vertical direction when the bogie, and dabber lower extreme and backstop seat when propping up mutually in vertical direction, and a series of linkage device can produce the variable rigidity in vertical direction. The invention can obviously improve the capability of the vehicle passing through the curve with small curvature radius, greatly saves primary suspension space and reduces the weight of the bogie.

Description

Method and structure for adjusting vertical rigidity of primary suspension device

Technical Field

The invention relates to the field of railway vehicles, in particular to a method and a structure for adjusting the rigidity of a primary suspension device in the vertical direction.

Background

The bogie with built-in axle boxes is a railway vehicle bogie with axle boxes arranged on the inner sides of wheel pairs, the bogie effectively reduces the space size of a framework, and the minimum curve of the bogie is obviously reduced compared with that of a common bogie through the radius, so that the turning maneuverability and flexibility of the bogie are greatly improved. In addition, the bogie of the type also meets the design requirement of light weight of the bogie to the maximum extent. In order to adapt to the geographic environment of mountains and curves in some countries in Europe, a vehicle is required to make a small turn frequently during running, and the vehicle is required to have strong small-curvature-radius passing capability.

The existing primary suspension devices are arranged on two sides of an axle box, and the rotation angle of a bogie in the structure is restricted by the primary suspension devices on two sides of the axle box when a vehicle turns with small curvature, so that the primary suspension devices are difficult to adapt to the geographic environment of some European countries with multiple mountains and multiple bends.

If the existing conical spring is directly arranged above the axle box, although the small-curvature turning can be well realized, the space above the axle box is extremely limited, especially the space in the transverse direction is very tight, and the difficulty in realizing various complex technical requirements of a series of suspension devices is high. The rigidity of the conical spring in the vertical direction, the transverse direction and the longitudinal direction is too small, so that the actual rigidity requirement of the vehicle on running is difficult to meet, and potential safety hazards exist when the vehicle runs. The load-bearing capacity and the shock absorption effect of the vehicle can be directly influenced by the rigidity of the vehicle in the vertical direction.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: how to improve the turning performance of the vehicle passing through a small curvature radius and ensure that the rigidity of a primary suspension device in the vertical direction meets the requirement of vehicle running.

In order to solve the problems, the technical scheme provided by the invention is as follows: a vertical rigidity adjusting structure of a primary suspension device comprises a base, a conical spring and a limiting stop, wherein the conical spring comprises a rubber body and a mandrel, a stop hole is formed in the lower end of a bogie, the upper end of the mandrel is installed in the stop hole of the bogie, and cavities are formed in the rubber body and the mandrel; the base is internally provided with two conical springs side by side along the longitudinal direction, a cavity of each conical spring is internally provided with a limiting stop which comprises a stop seat and a stop rod, and the stop rods are integrally formed above the stop seat; be equipped with the axle box seat on the axle box, the pedestal mounting produces relative movement in the axle box seat in vertical direction when the bogie, and dabber lower extreme and backstop seat when propping up mutually in vertical direction, and a series of linkage device can produce the variable rigidity in vertical direction.

Preferably, the conical spring further comprises an outer sleeve, an annular partition plate is embedded in the rubber body, the inner side of the upper end of the rubber body is connected with the outer side of the mandrel, and the outer side of the lower end of the rubber body is connected with the inner side of the outer sleeve; the mandrel comprises a mandrel body and a mandrel handle, and the mandrel handle is integrally formed above the mandrel body; the base comprises a bottom plate, a shell and a bridging part, the shell and the bridging part are integrally formed on the outer side of the bottom plate, the two sides of the bridging part are respectively provided with the shell, and the shell and the bridging part are connected together in a seamless mode.

Preferably, the outer side of the outer sleeve of the conical spring is tightly attached to the inner side of the shell of the base, so that the lower end of the conical spring is arranged in the base in an interference fit manner; the primary suspension device further comprises a top plate, wherein a shaft mounting hole is formed in the top plate, a shaft handle of the mandrel penetrates through the shaft mounting hole of the top plate and extends into a stopping hole of the bogie, and the shaft handle and the stopping hole are installed in a clearance fit mode.

Preferably, the shaft body comprises a shaft cylinder and a shaft cone, the shaft cone is integrally formed at the lower end of the shaft cylinder, the shaft cylinder is cylindrical, and the shaft cone is in an inverted cone shape; the outer sleeve comprises a sleeve body, a sleeve cone and a sleeve groove, the sleeve cone is integrally formed between the sleeve body and the sleeve groove, the sleeve body is in a circular tube shape, the diameter of the upper end of the inner side of the sleeve cone is larger than that of the lower end of the inner side of the sleeve cone, and the sleeve groove is a groove with the lower end of the outer sleeve sunken towards the inner side; the connection of the inner side of the upper end of the rubber body and the outer side of the mandrel is as follows: the inner side of the upper end of the rubber body is connected with the outer side of the shaft cone; the connection between the outer side of the lower end of the rubber body and the inner side of the outer sleeve means that: the outer side of the lower end of the rubber body is connected with the inner sides of the sleeve body and the sleeve cone of the outer sleeve.

Preferably, the middle parts of the mandrel, the rubber body and the outer sleeve are provided with cavities which are communicated with each other; the lower end of the limit stop catch is clamped in the base, and the upper end of the limit stop catch extends into a cavity formed in the middle of the mandrel.

Preferably, the limit stop comprises a stop seat and a stop rod, and the stop rod is integrally formed above the stop seat; the vertical section of the stop seat is a convex section, the lower end of the stop seat is a lower seat step, the upper end of the stop seat is an upper seat step, and a bottom mounting hole matched with the stop seat in shape and size is formed in the bottom plate; the lower end block of spacing backstop indicates in the base: the stop seat of the limit stop is clamped in the bottom mounting hole of the bottom plate, so that the lower seat step and the bottom plate are jacked in the vertical direction; the external diameter of going up the seat rank is greater than the internal diameter of the axis body lower extreme of dabber, and dabber lower extreme and spacing backstop are pushed up mutually and are: the lower surface of the shaft body is against the upper surface of the upper step.

A vertical stiffness adjusting method of a primary suspension device comprises a base, conical springs and limiting stoppers, wherein the conical springs comprise rubber bodies and mandrels, the two conical springs are arranged in the base side by side, the lower end of a bogie is provided with a stopper hole, the upper end of the mandrel is arranged in the stopper hole of the bogie, and the base is arranged at the top of an axle box; the cavity is formed in the conical spring, the limiting stop is arranged on the base, so that the bogie can move relative to the axle box in the vertical direction, and when the limiting stop is abutted against the lower end of the mandrel, the primary suspension device can change rigidity in the vertical direction.

Preferably, the conical spring further comprises an outer sleeve, the middle parts of the mandrel, the rubber body and the outer sleeve are provided with cavities which are communicated with each other, the limiting stop is clamped in the base, the lower end of the limiting stop extends out of the base, and the rigidity of the primary suspension device in the vertical direction is adjusted by adjusting the distance between the limiting stop and the lower end of the mandrel in the vertical direction.

Preferably, the outer side of the lower end of the mandrel and the inner side of the upper end of the outer sleeve are arranged into inverted cones, the inner side of the upper end of the rubber body is connected with the outer side of the lower end of the mandrel, and the outer side of the lower end of the rubber body is connected with the inner side of the upper end of the outer sleeve; the rigidity of the vertical direction of the suspension device can be achieved by adjusting the conicity of the outer side of the lower end of the mandrel and the inner side of the upper end of the outer sleeve and adjusting the thickness of the rubber body.

Preferably, the rubber body is internally provided with an inverted cone-shaped hollow partition plate, and the rigidity of the suspension device in the vertical direction can be achieved by adjusting the distance between the partition plate and the outer side of the mandrel, the distance between the partition plate and the inner side of the outer sleeve, the distance between adjacent partition plates and adjusting the taper, the thickness and the number of the partition plates.

The beneficial technical effects of the invention are as follows: the invention places a primary suspension device assembled by two conical springs in parallel on the top of an axle box, wherein the primary suspension device is in a rectangular shape, while the conventional primary suspension device is placed on two sides of the axle box and is in a round shape. Compared with the conventional primary suspension device, the primary suspension device can obviously improve the capability of a vehicle passing through a curve with a small curvature radius, greatly saves primary suspension space and reduces the weight of a bogie. The minimum curve passing radius of the bogie of the vehicle is obviously reduced compared with that of a common bogie, so that the turning maneuverability and flexibility of the bogie are greatly improved, and the load capacity, the dynamic performance and the critical speed of the whole vehicle are improved.

Drawings

FIG. 1 is a schematic view of an installation structure of a suspension system according to one embodiment;

FIG. 2 is a schematic view of the overall structure of a suspension system according to one embodiment;

FIG. 3 is a schematic perspective view of a base according to an embodiment;

FIG. 4 is a schematic cross-sectional view of a mandrel according to an embodiment;

FIG. 5 is a schematic cross-sectional view of the outer jacket according to the first embodiment;

FIG. 6 is a schematic cross-sectional view of a stop block according to an embodiment;

FIG. 7 is a schematic structural diagram of a base according to an embodiment;

FIG. 8 is a schematic structural diagram of a top plate according to an embodiment;

in the figure: 1 bogie, 11 stop holes, 2 top plates, 21 shaft mounting holes, 22 top grooves, 23 top lightening holes, 3 mandrels, 31 shaft handles, 32 shaft bodies, 321 shaft bodies, 322 shaft cones, 41 rubber bodies, 42 partition plates, 43 outer sleeves, 431 sleeve bodies, 432 sleeve cones, 433 sleeve grooves, 5 bases, 51 bottom plates, 52 shells, 53 bridging parts, 54 side lightening holes, 55 middle lightening holes, 56 bottom mounting holes, 61 stop seats, 611 lower steps, 612 upper steps, 62 stop rods, 7 cavities, 8 insulators and 9 shaft box seats.

Detailed Description

The invention is further described with reference to the following examples and figures:

example one

As shown in fig. 1 and 2, a primary suspension device includes a base 5, a top plate 2, a conical spring including a rubber body 41, a core shaft 3, and an outer sleeve 43, and a limit stopper. The lower end of the bogie 1 is provided with a stop hole 11, a single conical spring is a rotating body, two conical springs are arranged between the base 5 and the top plate 2 side by side along the longitudinal direction, and the upper ends of the mandrels 3 of the conical springs are arranged in the stop hole 11 in a clearance fit mode. The middle parts of the mandrel 3, the rubber body 41 and the outer sleeve 43 are all provided with cavities 7 which are communicated with each other, a stop seat 61 at the lower end of a limit stop is clamped in a bottom plate 51 at the lower end of the base 5 in an interference fit mode, and the upper end of the limit stop extends into the cavity 7 arranged at the middle part of the mandrel 3. The upper end and the lower end of the axle box seat 9 are provided with grooves, the axle box is clamped in the grooves at the lower end of the axle box seat 9, and the lower end of the base 5 of the conical spring is embedded in the grooves at the upper end of the axle box seat 9 in an interference fit mode.

As shown in fig. 2, 3, 4 and 5, the rubber body 41 is embedded with a ring-shaped partition plate 42, and both the rubber body 41 and the partition plate 42 are hollow and inverted cone-shaped, that is, the diameter of the upper end of the partition plate 42 is larger than that of the lower end of the partition plate 42. The mandrel 3 comprises a mandrel 31 and a mandrel body 32, the mandrel 31 is integrally formed above the mandrel body 32, the mandrel body 32 comprises a mandrel body 321 and a mandrel cone body 322, the mandrel cone body 322 is integrally formed at the lower end of the mandrel body 321, the mandrel body 321 is cylindrical, and the mandrel cone body 322 is in an inverted cone shape. The outer sleeve 43 comprises a sleeve body 431, a sleeve cone 432 and a sleeve groove 433, wherein the sleeve cone 432 is integrally formed between the sleeve body 431 and the sleeve groove 433, the sleeve body 431 is in a circular tube shape, the diameter of the upper end of the inner side of the sleeve cone 432 is larger than that of the lower end of the inner side of the sleeve cone 432, and the sleeve groove 433 is a groove in which the lower end of the outer sleeve 43 is recessed inwards. The mandrel 31 is installed in the stop hole 11 with a clearance fit, the inner side of the upper end of the rubber body 41 is connected with the outer side of the shaft cone 322, and the outer side of the lower end of the rubber body 41 is connected with the inner sides of the sleeve body 431 and the sleeve cone 432 of the outer sleeve 43. The insulator 8 is in a hollow round tube shape, and the insulator 8 is arranged on the inner side of the mandrel 3 in an interference fit mode.

The base 5 comprises a bottom plate 51, a shell 52 and a bridging part 53, the shell 52 and the bridging part 53 are integrally formed on the outer side of the bottom plate 51, the shell 52 is arranged on each of two sides of the bridging part 53, the shell 52 and the bridging part 53 are connected together in a seamless mode, and the cross section of the whole formed by connecting the shell 52 and the bridging part 53 is 8-shaped. Wherein the middle of the shell 52 and the bridge part 53 are both hollowed out, and the cross section of each shell 52 is C-shaped. The conical springs are rotational bodies, the lower ends of the two conical springs are installed in the housing 52 in an interference fit manner, and a bridge portion 53 is provided between the two housings 52 to prevent the two conical springs from interfering with each other when installed. In order to meet the requirement of light weight design of the vehicle, the bottom plate 51 and the bridging parts 53 are hollowed, the bottom plate 51 is provided with a middle lightening hole 55 penetrating through the bottom plate 51 at the position of the bridging parts 53, and the bottom plate 51 is further provided with side lightening holes 54 penetrating through the bottom plate 51 at the outer sides of the two stop seats 61.

As shown in fig. 2, 5 and 7, the limit stop includes a stop seat 61 and a stop rod 62, the stop rod 62 is integrally formed above the stop seat 61, the lower end of the stop seat 61 is a cylindrical lower step 611, the upper end of the stop seat 61 is a cylindrical upper step 612, and the vertical cross section of the stop seat 61 is a "convex" cross section. The bottom plate 51 is provided with a bottom mounting hole 56 with the shape and size matched with the stop seat 61, the vertical section of the bottom mounting hole 56 is also in a convex shape, and the stop seat 61 of the limit stop is clamped in the bottom mounting hole 56 of the bottom plate 51, so that the upper surface of the lower seat step 611 and the lower surface of the bottom plate 51 are propped in the vertical direction.

As shown in fig. 1, 2 and 8, through axle mounting holes 21 are formed on both sides of the top plate 2, a through top lightening hole 23 is formed in the middle of the top plate 2 to meet the requirement of vehicle light weight design, and a top groove 22 recessed inwards is further formed in the middle edge of the top plate 2. The positions of the two axle mounting holes 21 of the top plate 2 correspond to the positions of the two stop holes 11 formed in the lower end of the bogie 1, and the shanks 31 of the spindles 3 of the two conical springs are mounted in the stop holes 11 in a clearance fit manner. So that the lower ends of both conical springs are engaged in the foundation 5 and the upper ends of both conical springs are engaged in the bogie 1.

As shown in fig. 1-8, when the present invention is operated under a heavy load condition, the carriage applies a large pressure to the conical spring through the bogie 1, so that the rubber body 41 of the conical spring is greatly deformed in the vertical direction, and the distance H between the lower surface of the shaft body 32 of the spindle 3 and the upper surface of the upper step 612 of the stop seat 61 is small. At this time, the stiffness of the primary suspension device changes as follows: when the vehicle climbs a slope, descends the slope and vibrates through the gap of the steel rails, the load change in the vertical direction is generated, and particularly when an emergency brake occurs while the vehicle descends the slope, the load above the bogie 1 is greatly changed in the vertical direction. Therefore, the bogie 1 will bring the rubber body 41 to elastic deformation again in the vertical direction through the mandrel 3. When the two conical springs deform, the rubber body 41 is firstly blocked by the partition plate 42, the outer sleeve 43 and the outer shell 52, so that the vertical stiffness variation of the conical springs is greatly improved, and at the moment, the stiffness curve of the conical springs is increased in a large-amplitude nonlinear manner. Then the rubber body 41 is further deformed, so that the lower surface of the shaft body 32 of the mandrel 3 is abutted against the upper surface of the upper step 612 of the stop seat 61, and the mandrel 3 is rigidly contacted with the stop seat 61, so that the stop seat 61 can provide a large blocking force, and at the moment, the primary suspension device can generate a large vertical variable stiffness, so that the vertical stiffness curve of the primary suspension device shows a remarkable nonlinear increase.

However, if the vehicle is under full load and does not run, the distance H between the lower surface of the shaft body 32 of the spindle 3 and the upper surface of the upper step 612 of the stop seat 61 is very small, so that the spindle 3 and the stop seat 61 are rigidly abutted by small changes in vertical load in the running process of the vehicle, and therefore the primary suspension device frequently has large-amplitude variable rigidity in the vertical direction, the vertical buffering and damping performance of the vehicle is remarkably reduced, and the comfort level and riding experience of passengers are poor. Therefore, it is necessary to determine how large the large-amplitude nonlinear increase of the stiffness of the conical spring reaches according to the vehicle type of the vehicle, the maximum carrying capacity of the vehicle, the gradient of the track in the road, and other factors, and then perform the large-amplitude nonlinear increase of the stiffness to ensure that the buffer and damping performance of the vehicle and the safe and stable operation can be achieved at the same time.

As shown in fig. 2, in the present embodiment, the initial stiffness value of the primary suspension apparatus, which undergoes large-amplitude stiffness change in the lateral and longitudinal directions, can be adjusted by adjusting the distance W between the outside of the stopper rod 62 and the inside of the insulator 8, the larger the value of the distance W, the higher the initial stiffness value in the lateral and longitudinal directions. The initial stiffness values are: when the small-amplitude nonlinear increase of the stiffness of the conical spring reaches a large value, the large-amplitude variable stiffness is performed. In this embodiment, the initial stiffness value of the primary suspension device with greatly variable stiffness in the vertical direction can be adjusted by adjusting the distance H between the upper surface of the upper step 612 and the lower surface of the shaft body 32. The larger the value of the pitch H, the higher the initial stiffness value in the vertical direction.

It will be apparent that modifications and variations are possible without departing from the principles of the invention as set forth herein.

Claims

1. A vertical rigidity adjusting structure of a primary suspension device is characterized in that the primary suspension device comprises a base, a conical spring and a limiting stop, the conical spring comprises a rubber body and a mandrel, the lower end of a bogie is provided with a stop hole, the upper end of the mandrel is installed in the stop hole of the bogie, and cavities are formed in the rubber body and the mandrel; the base is internally provided with two conical springs side by side along the longitudinal direction, a cavity of each conical spring is internally provided with a limiting stop which comprises a stop seat and a stop rod, and the stop rods are integrally formed above the stop seat; the axle box is provided with an axle box seat, the base is arranged in the axle box seat, and when the bogie generates relative movement in the vertical direction relative to the axle box and the lower end of the central spindle and the stop seat are propped against each other in the vertical direction, the primary suspension device can generate variable rigidity in the vertical direction; the conical spring also comprises an outer sleeve, an annular partition plate is embedded in the rubber body, the inner side of the upper end of the rubber body is connected with the outer side of the mandrel, and the outer side of the lower end of the rubber body is connected with the inner side of the outer sleeve; the mandrel comprises a mandrel body and a mandrel handle, and the mandrel handle is integrally formed above the mandrel body; the base comprises a bottom plate, a shell and a bridging part, the shell and the bridging part are integrally formed on the outer side of the bottom plate, two sides of the bridging part are respectively provided with the shell, and the shell and the bridging part are connected together in a seamless mode; the shaft body comprises a shaft cylinder and a shaft cone, the shaft cone is integrally formed at the lower end of the shaft cylinder, the shaft cylinder is cylindrical, and the shaft cone is in an inverted cone shape; the outer sleeve comprises a sleeve body, a sleeve cone and a sleeve groove, the sleeve cone is integrally formed between the sleeve body and the sleeve groove, the sleeve body is in a circular tube shape, the diameter of the upper end of the inner side of the sleeve cone is larger than that of the lower end of the inner side of the sleeve cone, and the sleeve groove is a groove with the lower end of the outer sleeve sunken towards the inner side; the connection of the inner side of the upper end of the rubber body and the outer side of the mandrel is as follows: the inner side of the upper end of the rubber body is connected with the outer side of the shaft cone; the connection between the outer side of the lower end of the rubber body and the inner side of the outer sleeve means that: the outer side of the lower end of the rubber body is connected with the inner sides of the sleeve body and the sleeve cone of the outer sleeve; the middle parts of the mandrel, the rubber body and the outer sleeve are all provided with cavities which are communicated with each other; the lower end of the limit stop is clamped in the base, and the upper end of the limit stop extends into a cavity formed in the middle of the mandrel; the vertical section of the stop seat is a convex section, the lower end of the stop seat is a lower seat step, the upper end of the stop seat is an upper seat step, and a bottom mounting hole matched with the stop seat in shape and size is formed in the bottom plate; the lower end block of spacing backstop indicates in the base: the stop seat of the limit stop is clamped in the bottom mounting hole of the bottom plate, so that the lower seat step and the bottom plate are jacked in the vertical direction; the external diameter of going up the seat rank is greater than the internal diameter of the axis body lower extreme of dabber, and dabber lower extreme and spacing backstop are pushed up mutually and are: the lower surface of the shaft body is against the upper surface of the upper step.

2. The vertical stiffness adjustment structure of a primary suspension device according to claim 1, wherein the outer side of the outer casing of the conical spring abuts against the inner side of the outer casing of the base such that the lower end of the conical spring is installed in the base in an interference fit manner; the primary suspension device further comprises a top plate, wherein a shaft mounting hole is formed in the top plate, a shaft handle of the mandrel penetrates through the shaft mounting hole of the top plate and extends into a stopping hole of the bogie, and the shaft handle and the stopping hole are installed in a clearance fit mode.

3. A vertical stiffness adjusting method of a primary suspension device is realized according to the vertical stiffness adjusting structure of the primary suspension device, which is characterized in that the primary suspension device comprises a base, conical springs and limit stops, the conical springs comprise rubber bodies and mandrels, the two conical springs are arranged in the base side by side, stop holes are formed in the lower end of a bogie, the upper ends of the mandrels are arranged in the stop holes of the bogie, and the base is arranged on the top of an axle box; the cavity is formed in the conical spring, the limiting stop is arranged on the base, so that the bogie can move relative to the axle box in the vertical direction, and when the limiting stop is abutted against the lower end of the mandrel, the primary suspension device can change rigidity in the vertical direction.

4. The method for adjusting the vertical rigidity of the primary suspension device according to claim 3, wherein the conical spring further comprises an outer sleeve, a cavity is formed in the middle of the mandrel, the rubber body and the outer sleeve, the cavity is communicated with the cavity, the limit stop is clamped in the base, the lower end of the limit stop extends out of the base, and the vertical rigidity of the primary suspension device is adjusted by adjusting the vertical distance between the limit stop and the lower end of the mandrel.

5. The method for adjusting the vertical rigidity of a primary suspension device according to claim 4, wherein the outer side of the lower end of the mandrel and the inner side of the upper end of the outer sleeve are formed in an inverted cone shape, and the inner side of the upper end of the rubber body is connected with the outer side of the lower end of the mandrel and the outer side of the lower end of the rubber body is connected with the inner side of the upper end of the outer sleeve; the rigidity of the vertical direction of the primary suspension device can be adjusted by adjusting the conicity of the outer side of the lower end of the mandrel and the inner side of the upper end of the outer sleeve and adjusting the thickness of the rubber body.

6. The method for adjusting the vertical rigidity of the primary suspension device according to claim 5, wherein the rubber body is provided with inverted conical hollow partition plates, and the vertical rigidity of the primary suspension device can be adjusted by adjusting the distance between the partition plates and the outer side of the mandrel, or the distance between the partition plates and the inner side of the outer sleeve, or the distance between adjacent partition plates, and adjusting the taper, the thickness and the number of the partition plates.