KR20200138373A - Shaft box suspension device and bogie vehicle equipped with the same - Google Patents

Abstract

The present invention provides a shaft box suspension device and a bogie vehicle having the same, wherein the shaft box suspension device includes an end wheel set module, and the end wheel set module includes a first wheel set; A first shaft box including a first support part and a second support part and installed on the first wheel set; A first cushioning part installed on the first support; A second buffer part installed on the second support; A first saddle installed between the first wheel set and the first shaft box; A first guide frame installed on the first shock absorber and having a first positioning plate opposite to the side plate of the first shaft box; A first inclined wedge structure whose bottom surface is connected to the second buffer part; A second guide frame installed on the inclined surface of the first inclined wedge structure; And a third cushioning part installed between the first saddle and the first shaft box. According to the technical solution of the present invention, it is possible to solve a problem in which the dynamic performance of the shaft box suspension device of the existing technology is not stable.

Description

Shaft box suspension device and bogie vehicle equipped with the same

The present invention relates to the technical field of a bogie, and more particularly, to an axle box suspension device and a bogie having the same.

Currently, railway freight cars are generally composed of a vehicle body, a bogie, a brake device, a coupler shock absorber, and the like. Here, the bogie supports the vehicle body, guides the vehicle to travel along the track, and serves to handle various loads received from the vehicle body and rail, and the bogie bogie is an important component of a railroad truck, which affects the dynamic performance of the vehicle. It is a key part. The main characteristic of the 3-axis bogie is that the number of axes is larger and the fixed wheelbase is larger than the conventional 2-axis bogie bogie consisting of three parts.

Among the prior art, a welded frame-type 3-axis bogie for railway freight cars is generally composed of a frame assembly, a basic brake device, a shaft box suspension device, and an elastic side bearing, and the shaft box suspension device is mounted on three wheel sets and wheel sets. It is composed of a shaft box, spring, inclined wedge and saddle. The curve-passing performance, high-speed driving safety and safety performance of a railroad vehicle equipped with a 3-axis bogie are important indicators for evaluating the vehicle, and the shaft box suspension system of the bogie bogie is related to the dynamic performance of the vehicle, and the dynamic performance of the vehicle is evaluated. You decide and influence yourself.

Among the prior art, the shaft box suspension device of the bogie is composed of a spring, an inclined wedge, a saddle and a shaft box. The double inclined wedge structure is applied to the end wheel set of the bogie, and the intermediate wheel set does not have the inclined wedge. The saddle is installed in the shaft box and is located between the shaft box and the bearing. The end wheel set is positioned by the symmetrical structure of both sides of the inclined surface of the inclined wedge and the friction force, so it is very difficult to determine the position of the balance point and belongs to an unstable structure. The intermediate wheelset is positioned by the strength of the spring in the horizontal and vertical directions, and the strength of the shaft box spring itself is small, so the dynamic performance of the vehicle is not stable. In addition, in the existing technology, birds are installed in the shaft box, and the top surface of the saddle and the top surface of the shaft box are matched between metal and metal, so wear is easily generated.

A three-axis bogie was disclosed in a patent application with an application number of CN200920100324. In this three-axis bogie, a single-sided inclined wedge structure is applied to the end wheel set, and there is no inclined wedge structure in the middle wheel set, and the shaft box is directly Matches the bearing. In a patent application with an application number of CN200920279848, a three-axis bogie of a railroad freight car was disclosed. In this three-axis bogie, the end wheel set has both sides inclined wedge structure, and the middle wheel set has no inclined wedge structure. Birds are installed between the and bearings. The dynamic performance of these two structures is not stable and wear is high.

The main object of the present invention is to provide an axial box suspension device and a bogie having the same, which solves the problem in which the dynamic performance of the axial box suspension device is not stable.

In order to realize the above object, according to an aspect of the present invention, an end wheel set module is included, and the end wheel set module includes a first wheel set; A first shaft box including a first support part and a second support part, and installed on the first wheel set; A first cushioning part installed on the first support; A second buffer part installed on the second support; A first saddle installed between the first wheel set and the first shaft box; A first positioning plate installed on the first cushioning part and installed opposite to the side plate of the first shaft box, and positioned by matching the side plate of the first shaft box by the first positioning plate. Guide frame; A first inclined wedge structure whose bottom surface is connected to the second buffer part; A second guide frame installed on the inclined surface of the first inclined wedge structure; And it provides a shaft box suspension device including a third cushioning part installed between the first saddle and the first shaft box.

In a further step, the third buffer part includes a first buffer plate; A second buffer plate installed to face the first buffer plate and having a buffer section between the first buffer plate; And a connecting part installed between the first buffer plate and the second buffer plate.

Further, the first buffer plate has a buffer concave surface on one side close to the second buffer plate, the second buffer plate has a buffer convex surface on one side close to the first buffer plate, and the buffer concave surface and the buffer convex surface Are installed to face each other, and the gap between the buffer convex surface and the buffer concave surface forms a buffer section.

Further, the first buffer plate and/or the second buffer plate are made of an elastic material.

Further, the third buffer part further includes a first positioning portion provided on the first buffer plate and/or the second buffer plate, and is positioned by the first positioning portion.

Further, the end wheel set module further includes a first wear part installed between the first positioning plate and the side plate of the first shaft box, and reduces wear of the first positioning plate by the first wear part.

Further, the end wheel set module further includes a second wear part installed between the first inclined wedge structure and the side plate of the first shaft box, and reduces wear of the first inclined wedge structure by the second wear part.

Taking a further step, the shaft box suspension device further includes an intermediate wheel set module, and the intermediate wheel set module includes a second wheel set installed at a distance from the first wheel set; A second shaft box installed on the second wheel set and including a third support part and a fourth support part; A fourth buffer part installed on the third support; A fifth cushioning part installed on the fourth support; A second saddle installed between the second wheel set and the second shaft box; A second inclined wedge structure installed on the fourth buffer part; And a third inclined wedge structure installed on the fifth cushioning part.

Taking a further step, the third inclined wedge structure is the same as the second inclined wedge structure, and the third inclined wedge structure and the second inclined wedge structure are symmetrically installed on the second shaft box.

Further, the shaft box suspension device further includes a sixth shock absorbing part provided between the second saddle and the second shaft box, and realizes shock absorbing by the sixth shock absorbing part.

Taking a further step, the first inclined wedge structure is installed on one side of the first shaft box close to the second shaft box.

Further, the shaft box suspension device includes two end wheel set modules and one intermediate wheel set module installed between the two end wheel set modules.

According to another aspect of the present invention, there is provided a bogie vehicle including the above-described shaft box suspension device.

According to the technical solution of the present invention, since the first positioning plate of the first guide frame is positioned by matching with the side plate of the first shaft box, the longitudinal rigidity of positioning is provided. The lower part of the first inclined wedge structure is a second buffer part, and the second buffer part provides support to the first inclined wedge structure, and a component force is generated by the inclined surface of the first inclined wedge structure, and the first positioning plate and It balances the force between the side plates of the first shaft box to provide a large longitudinal positioning strength. In addition, by reasonably setting the positioning strength of the third cushioning part in the longitudinal and transverse directions, it is possible to realize a good dynamic performance effect and improve the stability of the dynamic performance. Therefore, according to the technical solution of the present invention, it is possible to solve a problem in which the dynamic performance of the shaft box suspension device of the existing technology is not stable.

The drawings constituting a part of the present application are for further understanding of the present invention, and exemplary embodiments and descriptions of the present invention are for interpreting the present invention and are not intended to limit the present invention.
1 is a schematic structural diagram of a shaft box suspension device according to a first embodiment of the present invention.
2 is a schematic structural diagram of an end wheel set module according to Embodiment 1 of the present invention.
3 is a schematic structural diagram of an intermediate wheel set module according to Embodiment 1 of the present invention.
4 is a front view of a first shaft box according to a first embodiment of the present invention.
5 is a plan view of a first shaft box according to Embodiment 1 of the present invention.
6 is a front view of a third buffer component according to a first embodiment of the present invention.
7 is a plan view of a third buffer part according to a first embodiment of the present invention.
8 is a left side view of a third buffer component according to a first embodiment of the present invention.
9 is a front view showing the first birds according to the first embodiment of the present invention.
10 is a plan view of a first saddle according to Example 1 of the present invention.
11 is a left side view of the first bird according to the first embodiment of the present invention.

However, as long as there is no contradiction, the embodiments of the present application and features of the embodiments may be combined with each other. The present invention will be described in detail through examples with reference to the drawings below.

As shown in Figs. 1 to 11, in Embodiment 1 of the present invention, a shaft box suspension device is provided, which includes an end wheel set module 10. As shown in FIG. 2, the end wheel set module 10 includes a first wheel set 11, a first shaft box 12, a first shock absorbing part 13, a second shock absorbing part 14, and a first A saddle 15, a first guide frame 16, a first inclined wedge structure 17, a second guide frame 110, and a third cushioning part 18 are included. Here, the first shaft box 12 is installed on the first wheel set 11, and as shown in FIGS. 4 and 5, the first shaft box 12 has a first support part 121 and a second A support part 122 is included, and the first buffer part 13 is installed on the first support part 121, and the second buffer part 14 is provided on the second support part 122. The first saddle 15 is installed between the first wheel set 11 and the first shaft box 12, and the structure of the first saddle 15 is shown in FIGS. 9 to 11. The first guide frame 16 is installed on the first cushioning part 13 and includes a first positioning plate 161 installed to face the side plate of the first shaft box 12, and the first positioning The plate 161 matches and is positioned with the side plate of the first shaft box 12. Specifically, the side plate in the present embodiment is installed connected to both the first support portion 121 and the second support portion 122.

Specifically, the first positioning plate 161 in this embodiment is installed at one end close to the first shaft box 12 of the first guide frame 16, and the side plate of the first shaft box 12 It can be installed at intervals, and is matched and positioned through contact between the first positioning plate 161 and the first shaft box 12 during the operation process. The bottom surface of the first inclined wedge structure 17 is connected to the second buffer part 14, the second guide frame 110 is installed on the inclined surface of the first inclined wedge structure 17, and the third buffer part ( 18) is installed between the first saddle 15 and the first shaft box 12. The first wheel set 11 is provided with a first bearing, and the first saddle 15 is installed on the first bearing.

According to the shaft box suspension device according to the present embodiment, the first positioning plate 161 of the first guide frame 16 contacts the side plate of the first shaft box 12 to match and position the first shaft box 12 during the operation process. , Provides longitudinal rigidity of positioning. The lower portion of the first inclined wedge structure 17 is a second buffer part 14, the second buffer part 14 provides support to the first inclined wedge structure 17, and the first inclined wedge structure 17 A component force is generated by the inclined surface of the first positioning plate 161 and the side plate of the first shaft box 12 to provide a large longitudinal positioning strength by balancing the force. In addition, by reasonably setting the positioning strength of the third buffer part 18 in the vertical direction and the horizontal direction, the strength of the positioning of the first positioning plate 161 is relaxed and a constant elastic positioning is provided. It can realize good dynamic performance effect, and continuously and stably secure the dynamic performance of the vehicle. A situation in which abrasion occurs due to direct contact between the first shaft box and the first saddle 15 by the third buffer part 18 can be avoided, and abrasion can be reduced.

Specifically, the first cushioning part 13 may be a spring. Alternatively, the second cushioning part 14 may be a spring. Alternatively, both the first shock absorbing part 13 and the second shock absorbing part 14 may be springs. In this embodiment, both the first shock absorbing part 13 and the second shock absorbing part 14 can be made of springs so as to better exhibit the shock absorbing action.

Specifically, as shown in FIGS. 6 to 8, the third buffer part 18 in this embodiment includes a first buffer plate 181, a second buffer plate 182, and a connection part 183. do. The second buffer plate 182 is installed to face the first buffer plate 181, and has a buffer section between the first buffer plate 181 and the second buffer plate 182, and the connection part 183 Is installed between the first buffer plate 181 and the second buffer plate 182. With this configuration, when the first buffer plate 181 or the second buffer plate 182 is pressed, the buffer section between the first buffer plate 181 and the second buffer plate 182 favorably exerts a buffering action. Thus, good dynamic performance effects can be realized. Specifically, by reasonably setting parameters such as the structure, size, and material of the first buffer plate 181, the second buffer plate 182 and the connecting part 183, the longitudinal direction and the corresponding third buffer part 18 The strength of positioning in the transverse direction can be obtained, and the dynamic performance effect can be further improved.

In order to further improve the dynamics performance effect, the first buffer plate 181 in this embodiment has a buffer concave surface 1811 on one side close to the second buffer plate 182, and the second buffer plate 182 ) Has a buffer convex surface 1821 on one side close to the first buffer plate 181, the buffer concave surface 1811 and the buffer convex surface 1821 are installed to face each other, and the buffer convex surface 1821 and The gap between the buffer concave surfaces 1811 forms a buffer section. With this configuration, when the first buffer plate 181 or the second buffer plate 182 is pressed, the distance between the buffer concave surface 1811 and the buffer convex surface 1821 is changed, and the buffer section is changed, thereby buffering the buffer. By exerting the action better, more stable dynamic performance effects can be realized.

Specifically, the first buffer plate 181 may be made of an elastic material, or the second buffer plate 182 may be made of an elastic material, or the first buffer plate 181 and the second buffer plate 182 All can be made of elastic materials. In this embodiment, both the first buffer plate 181 and the second buffer plate 182 are made of an elastic material so as to better exhibit the buffer effect. Specifically, both the first buffer plate 181 and the second buffer plate 182 may be rubber pads.

In this embodiment, the third buffer component 18 further includes a first positioning portion 184, and is positioned by the first positioning portion 184. The first positioning unit 184 may be installed on the first buffer plate 181, or the first positioning unit 184 may be installed on the second buffer plate 182, or the first buffer plate 181 ) And the second buffer plate 182 may be provided with a first positioning unit 184. Specifically, in this embodiment, the first positioning unit 184 is provided at one end of the first buffer plate 181 away from the second buffer plate 182, and the second buffer plate 182 is 1 A first positioning part 184 is installed at one end away from the buffer plate 181, and the first positioning part 184 positions the first shaft box 12 and the first saddle 15, respectively. It is determined to improve the accuracy of positioning, and a phenomenon in which the position of the third buffer part 18 is displaced during the operation process, resulting in poor buffering effect, can be avoided, and more excellent dynamics performance can be realized.

Specifically, a second positioning unit is installed in the first shaft box 12, a third positioning unit is installed in the first saddle 15, and the second positioning unit is provided with the first positioning unit 184 and Matching is for realizing positioning, and the third positioning unit is matched with the first positioning unit 184 to realize positioning. Through this configuration, it is possible to better position the third buffer component 18, and a better dynamic performance effect can be realized.

In this embodiment, the end wheel set module 10 further includes a first wear part 191, and the first wear part 191 includes a first positioning plate 161 and a first shaft box 12 It is installed between the side plates of and reduces wear of the first positioning plate 161 through the first wear part 191. Specifically, in this embodiment, the first wear part 191 may be installed on the first positioning plate 161, and the first wear part 191 may be made of a non-metal material or a metal material, The first wear part 191 may be a wear plate.

Specifically, the end wheel set module 10 in this embodiment further includes a second wear part 192, and the second wear part 192 includes a first inclined wedge structure 17 and a first shaft box ( It is installed between the side plates of 12), and reduces wear and tear of the first inclined wedge structure 17 through the second wear part 192. Specifically, the second wear part 192 is installed on the side plate of the first inclined wedge structure 17, and the side plate of the first inclined wedge structure 17 is provided with the bottom surface of the first inclined wedge structure 17 It is located between the slopes. The second wear part 192 may be made of a metal material or a non-metal material, and the second wear part 192 may be a wear plate. In this embodiment, the second wear part 192 may be made of a non-metallic material such as leather, and the second wear part 192 contacts the side plate of the shaft box, thereby forming the second wear part 192. Through this, friction between the first shaft box 12 and the first inclined wedge structure 17 can be reduced, while at the same time, a constant vibration reduction and buffering action can be exhibited.

As shown in Fig. 3, in this embodiment, the shaft box suspension device further includes an intermediate wheel set module 20. The intermediate wheel set module 20 includes a second wheel set 21, a second shaft box 22, a fourth shock absorber 23, a fifth shock absorber 24, a second saddle 25, and a second slope. A wedge structure 26 and a third oblique wedge structure 27 are included. Here, the second wheel set 21 is installed at a distance from the first wheel set 11, the second shaft box 22 is installed in the second wheel set 21, and the second shaft box ( 22) includes a third support 221 and a fourth support 222, the fourth buffer part 23 is installed on the third support 221, and the fifth buffer part 24 is a fourth support part It is installed at 222, and the second saddle 25 is installed between the second wheel set 21 and the second shaft box 22. The second inclined wedge structure 26 is provided on the fourth buffer part 23. The third inclined wedge structure 27 is installed on the fifth buffer part 24. In this embodiment, both the third shock absorbing part 18 and the fourth shock absorbing part 23 are springs. The second wheel set 21 is provided with a second bearing, and the second saddle 25 is installed on the second bearing.

Specifically, the second shaft box 22 may have the same structure as the first shaft box 12, and the second saddle 25 may have the same structure as the first saddle 15. Both the first shaft box 12 and the second shaft box 22 may have a symmetrical structure.

In the intermediate wheel set module 20 of this structure, the fourth buffer part 23 under the second inclined wedge structure 26 and the fifth buffer part 24 under the third inclined wedge structure 27 are pressed. When a bearing force is generated, the horizontal component force of the inclined surface of the second inclined wedge structure 26 and the horizontal component force of the inclined surface of the third inclined wedge structure 27 are balanced with each other to achieve a good dynamic performance effect.

Specifically, in this embodiment, the third inclined wedge structure 27 and the second inclined wedge structure 26 have the same structure, and the third inclined wedge structure 27 and the second inclined wedge structure 26 are symmetrically formed. 2 It is installed in the shaft box (22). By installing in such a symmetrical structure, the stability of the dynamics performance can be further improved.

In this embodiment, the intermediate wheel set module 20 further includes a sixth shock absorbing part 28, and the sixth shock absorbing part 28 is between the second saddle 25 and the second shaft box 22. It is installed, and buffering is performed through the sixth buffer part 28. By reasonably setting the positioning strength of the sixth shock absorbing part 28 in the longitudinal and transverse directions, it is possible to realize a good dynamic performance effect. In addition, by installing the sixth cushioning part 28, it is possible to avoid direct contact of the second shaft box 22 to the second saddle 25, and furthermore, the second shaft box 22 and the second saddle 25 ), the wear of the whole device can be reduced by avoiding the wear. Specifically, the sixth buffer part 28 in the present embodiment may have the same structure as the third buffer part 18.

In order to further reduce wear, a second wear part 192 is installed on one side of the second inclined wedge structure 26 close to the second shaft box 22, and the second wear part 192 The wear between the inclined wedge structure 26 and the side plate of the second shaft box 22 is reduced. A second wear part 192 is also installed on one side of the third inclined wedge structure 27 close to the second shaft box 22, and the third inclined wedge structure 27 and the third inclined wedge structure 27 through the second wear part 192 Reduces wear between the second shaft box (22).

In this embodiment, the intermediate wheel set module 20 further includes a third guide frame 291 and a fourth guide frame 292, and the third guide frame 291 has a second inclined wedge structure 26 It is installed on the top, and the fourth guide frame 292 is installed on the third inclined wedge structure 27. The inclined surface of the third guide frame 291 is installed to face each other with the inclined surface of the second inclined wedge structure 26, and the inclined surface of the fourth guide frame 292 is with the inclined surface of the third inclined wedge structure 27 It is installed oppositely, and positioning is more effective through matching of the third guide frame 291 and the second inclined wedge structure 26, and matching of the fourth guide frame 292 and the third inclined wedge structure 27. And can provide good dynamics performance.

Specifically, the first inclined wedge structure 17 may be installed on one side away from the second shaft box 22 of the first shaft box 12, or the second shaft box of the first shaft box 12 ( It can be installed on one side close to 22). In this embodiment, the first inclined wedge structure 17 is installed on one side of the first shaft box 12 close to the second shaft box 22. By this configuration, the stability of the dynamics performance can be further improved.

Specifically, as shown in Fig. 1, the shaft box suspension device in the present embodiment includes two end wheel set modules 10 and one intermediate wheel set module 20, and the intermediate wheel set module 20 Is installed between the two end wheel set modules 10 and the two end wheel set modules 10 at intervals. According to the axial box suspension device in this embodiment, it is possible to provide stability of good dynamics performance.

In the second embodiment of the present invention, a bogie is provided, wherein the bogie includes an axle box suspension device and a frame 30, wherein the axial box suspension device is an axial box suspension device according to the first embodiment. The frame 30 in this embodiment is installed on the first guide frame 16, the second guide frame 110, the third guide frame 291 and the fourth guide frame 292.

From the above description, it can be seen that the above-described embodiments of the present invention can realize the following technical effects. That is, technical upgrades can be realized by effectively improving the dynamics performance of the vehicle, securing continuous stability of the dynamics performance of the vehicle to improve safety and reliability, and between the first shaft box 12 and the first saddle 15 Abrasion-free and abrasion-free between the second shaft box 22 and the second saddle 25 are realized to reduce maintenance costs, and a third cushioning part 18 is installed in the first shaft box 12 2 By installing the sixth shock absorbing part 28 in the shaft box 22, the elastic positioning of the end wheel set module 10 and the intermediate wheel set module 20 is realized, and a function of low power is provided.

However, the terms used herein are for describing specific embodiments and are not intended to limit exemplary embodiments of the present application. Unless clearly indicated in the preceding or subsequent context, the singular form used herein includes the plural form as well, and features, steps, operations, elements, modules and/or when used in the specification "contains" and/or "includes" It says that a combination of these exists.

Unless specifically stated otherwise, the relative arrangement, numerical expression method, and numerical values of the parts and steps described in these embodiments do not limit the scope of the present invention. In addition, for convenience of explanation, the size of each part shown in the drawings is not created according to an actual ratio relationship. Known technologies, methods, and devices by those skilled in the art have not been described in detail, but where appropriate, such technologies, methods, and devices should be recognized as part of the specification. In all examples disclosed and described herein, all specific values should be interpreted as illustrative rather than limiting. Therefore, it may be a different value in other examples of the exemplary embodiment. Here, since similar symbols and letters denote similar items in the drawings, if one item is defined in one drawing, it will not be further described in subsequent drawings.

In describing the present invention, the orientation or positional relationship indicated by the defense company such as “before, after, top, bottom, left, right”, “horizontal, vertical, vertical, horizontal”, and “normal, floor” is shown in the drawings. It is intended to facilitate and simplify the description of the present invention as being based on one orientation or positional relationship, and such a defense company indicates that the device or element must have a specified orientation or be configured and operated in a specified orientation. It is not to be or imply. Therefore, it should not be understood as limiting the protection scope of the present invention. Defense company “inside, outside” refers to inside and outside the contours of each part itself.

For convenience of explanation, relative terms of space, for example “… Is above”, “… Is on the upper side”, “… “On the top”, “top”, etc. are for explaining the spatial positional relationship between the device or feature shown in the drawings and other devices or features. Here, the relative terms of space include other orientations in use or operation processes other than the orientation shown in the diagram of the device. For example, if the device shown in the drawing is installed in the opposite direction, the device described as "is above the other device or structure" or "is above the other device or structure" is "is below the other device or structure" or " It is positioned as “under the other device or structure”. Hence the exemplary term “… “It’s on the top” means “… On the upper side” and “… It includes two orientations of "is on the bottom". The element may be positioned in other ways (rotating 90 degrees, or other orientation), and interpreted for the relative description of space here.

And when a component is limited by terms such as “first” and “second”, it is only for distinguishing the component, and unless otherwise specified, the term does not have a special meaning, so it is understood as limiting the protection scope of the present invention. Can not be done.

The above is a preferred embodiment of the present invention, and does not limit the present invention, and various changes and changes can be made to the present invention for those skilled in the art. All modifications, equivalent replacements, and improvements made within the scope of the spirit and principle of the present invention all fall within the scope of protection of the present invention.

10: end wheel set module
11: 1st wheel set
12: 1st axis box
121: first support
122: second support
13: first cushioning part
14: second buffer part
15: first birds
16: first guide frame
161: first positioning plate
17: first inclined wedge structure
18: 3rd buffer part
181: first buffer plate
1811: buffer concave surface
182: second buffer plate
1821: buffer convex surface
183: connecting parts
184: first positioning unit
191: first wear part
192: second wear part
110: second guide frame
20: middle wheel set module
21: second wheel set
22: 2nd axis box
221: third support
222: fourth support
23: 4th buffer part
24: 5th buffer part
25: second birds
26: second inclined wedge structure
27: 3rd inclined wedge structure
28: 6th buffer part
291: third guide frame
292: fourth guide frame
30: frame.

Claims (13)

Including the end wheel set module 10,
The end wheel set module 10,
A first wheelset 11;
A first shaft box (12) including a first support part (121) and a second support part (122) and installed on the first wheel set (11);
A first buffer part 13 installed on the first support part 121;
A second buffer part 14 installed on the second support part 122;
A first saddle (15) installed between the first wheel set (11) and the first shaft box (12);
It is installed on the first buffer part 13, includes a first positioning plate 161 installed to face the side plate of the first shaft box 12, by the first positioning plate 161 A first guide frame (16) matched and positioned with the side plate of the first shaft box (12);
A first inclined wedge structure (17) whose bottom surface is connected to the second buffer part (14);
A second guide frame 110 installed on an inclined surface of the first inclined wedge structure 17; And
A shaft box suspension device comprising a third buffer part (18) installed between the first saddle (15) and the first shaft box (12). The method of claim 1,
The third cushioning part 18,
A first buffer plate 181;
A second buffer plate 182 installed to face the first buffer plate 181 and having a buffer section between the first buffer plate 181; And
A shaft box suspension apparatus comprising a connecting part (183) installed between the first buffer plate (181) and the second buffer plate (182). The method of claim 2,
The first buffer plate 181 has a buffer concave surface 1811 on one side close to the second buffer plate 182, and the second buffer plate 182 is close to the first buffer plate 181 A buffer convex surface 1821 is provided on one side, and the buffer concave surface 1811 and the buffer convex surface 1821 are installed to face each other, and between the buffer convex surface 1821 and the buffer concave surface 1811 Shaft box suspension device, characterized in that the gap of the forming the buffer section. The method of claim 2,
The first buffer plate (181) and/or the second buffer plate (182) is made of an elastic material. The method of claim 2,
The third cushioning part 18,
Further comprising a first positioning unit 184 installed on the first buffer plate 181 and/or the second buffer plate 182, characterized in that the position is determined by the first positioning unit 184 Shaft box suspension system The method of claim 1,
The end wheel set module 10,
A first wear part 191 installed between the first positioning plate 161 and the side plate of the first shaft box 12 is further included, and the first position by the first wear part 191 Shaft box suspension device, characterized in that to reduce the wear of the crystal plate (161). The method of claim 1,
The end wheel set module 10,
The first inclined wedge structure 17 and a second wear part 192 installed between the side plate of the first shaft box 12 is further included, the first inclination by the second wear part 192 Shaft box suspension device, characterized in that to reduce the wear and tear of the wedge structure (17). The method of claim 1,
Further comprising an intermediate wheel set module 20,
The intermediate wheel set module 20,
A second wheel set (21) installed at a distance from the first wheel set (11);
A second shaft box (22) installed on the second wheel set (21) and including a third support portion (221) and a fourth support portion (222);
A fourth buffer part 23 installed on the third support part 221;
A fifth buffer part 24 installed on the fourth support part 222;
A second saddle (25) installed between the second wheel set (21) and the second shaft box (22);
A second inclined wedge structure (26) installed on the fourth buffer part (23); And
A shaft box suspension apparatus comprising a third inclined wedge structure (27) installed on the fifth buffer part (24). The method of claim 8,
The third inclined wedge structure 27 has the same structure as the second inclined wedge structure 26, and the third inclined wedge structure 27 and the second inclined wedge structure 26 are the second shaft box ( A shaft box suspension device, characterized in that it is installed symmetrically to 22). The method of claim 8,
A shaft, characterized in that it further comprises a sixth shock absorbing part 28 installed between the second saddle 25 and the second shaft box 22, and realizes shock absorbing by the sixth shock absorbing part 28 Box suspension system. The method of claim 8,
The first inclined wedge structure (17) is a shaft box suspension device, characterized in that installed on one side of the first shaft box (12) close to the second shaft box (22). The method of claim 8,
And one said intermediate wheel set module (20) installed between said two end wheel set modules (10) and two said end wheel set modules (10). A bogie car comprising the axial box suspension device according to any one of claims 1 to 12.

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