CN210265867U - Combined load-carrying device for mechanical seal and thrust bearing - Google Patents

Abstract

The application relates to a mechanical seal and thrust bearing combined bearing device, wherein the mechanical seal device and the thrust bearing are jointly arranged on a rotating shaft. The mechanical sealing device comprises a thrust bearing, a shell, a first movable ring, a second movable ring, a first static sealing assembly and a second static sealing assembly. The housing encloses a first space for storing fluid under pressure. The first and second rotating ring surfaces create a pressure differential in a first direction. The first rotating ring and the second rotating ring are fixedly connected with the rotating shaft. The first rotating ring and the second rotating ring generate an axial thrust in a first direction to the rotating shaft. The first direction is in line with the thrust bearing output axial load direction. When the rotating shaft needs a certain axial thrust to maintain operation, the mechanical sealing device and the thrust bearing jointly provide the axial thrust, the working load of the thrust bearing is reduced, and the reliability of the thrust bearing is improved.

Description

Mechanical seal and thrust bearing combined bearing device

Technical Field

The application relates to the technical field of machinery, in particular to a mechanical seal and thrust bearing combined bearing device.

Background

The large thrust bearing is generally adopted as a bearing part in the fields of nuclear power, water pumps and the like in China, and the working performance of the large thrust bearing plays a vital role in the rotating part of the whole unit. The research on the aspects of thrust bearing structure, performance, installation and the like has been widely developed in China.

The bearing capacity of the thrust bearing can be improved really by singly improving the structure and the performance of the thrust bearing, but the design of the bearing bush material, the support form and the shape of the bush surface is complex, and the cost and the uncertainty of the test are increased. The large thrust bearing bears the limit rotation speed and the limit load under the working conditions of high rotation speed and high load, and the problem of reliability reduction still exists.

SUMMERY OF THE UTILITY MODEL

Based on this, it is necessary to provide a combined bearing device of a mechanical seal and a thrust bearing, which is used for being matched with the thrust bearing to increase the reliability of the thrust bearing, aiming at the problem that the reliability of a large thrust bearing is reduced when the large thrust bearing bears the limit rotation speed and the limit load under the working conditions of high rotation speed and high load.

A mechanical seal and thrust bearing combined bearing device is used for reducing axial load of a rotating shaft and comprises a thrust bearing, a shell, a first movable ring, a second movable ring, a first static seal assembly and a second static seal assembly.

The thrust bearing is sleeved on the rotating shaft. The housing encloses a first space for storing fluid under pressure. The housing and the thrust bearing are arranged at intervals. The housing has a first opening and a second opening disposed opposite to each other. The first opening and the second opening are used for penetrating through the rotating shaft. The area of the first opening is larger than the area of the second opening. The direction of the second opening pointing to the first opening is a first direction, and the first direction is consistent with the axial thrust direction of the counteracting axial load force generated by the thrust bearing.

The first movable ring is accommodated in the first space and is fixedly sleeved on the rotating shaft. The first rotating ring is provided with a first surface and a second surface which are oppositely arranged, and the first surface is arranged close to the first opening. The second movable ring is accommodated in the first space, is fixedly sleeved on the rotating shaft and is positioned on one side of the first movable ring, which is far away from the first opening. The second rotating ring has third and fourth opposing surfaces. The fourth surface is attached to the second surface. The diameter of the first rotating ring is larger than that of the second rotating ring.

The edge of the first opening is bent towards the first space and extends to the first surface to form a first bent part. The edge of the second opening faces the first space and extends to the third surface to form a second bending part. The rotation axis passes through the first bending part and the second bending part. The first static sealing assembly is accommodated in the first space and is arranged around the first bending part. One end of the first static sealing component is abutted against the inner wall of the shell. The other end of the first static seal component is abutted against the first surface. The second static sealing assembly is accommodated in the first space and is arranged around the second bending part. One end of the second static sealing component is abutted against the inner wall of the shell, and the other end of the second static sealing component is abutted against the third surface.

In one embodiment, the first static seal assembly includes a first static ring and a first resilient element. The first stationary ring is sleeved on the first bending part and provided with a fifth surface and a sixth surface which are opposite to each other. The fifth surface is attached to the first surface. One end of the first elastic element is fixed on the inner wall of the shell, and the other end of the first elastic element abuts against the sixth surface and is connected with the first stationary ring.

In one embodiment, the second static seal assembly includes a second static ring and a second resilient element. The second stationary ring is sleeved on the second bending part and provided with a seventh surface and an eighth surface which are opposite to each other. The seventh surface is attached to the third surface. One end of the second elastic element is fixed on the inner wall of the shell, and the other end of the second elastic element abuts against the eighth surface and is connected with the second stationary ring.

In one embodiment, the first elastic elements are multiple and are circumferentially arranged at intervals along the first bending part.

In one embodiment, the first bending portion is a circular ring structure, an outer diameter of the first stationary ring is the same as an outer diameter of the first movable ring, and an inner diameter of the first stationary ring is the same as a diameter of the first bending portion.

In one embodiment, the second stationary ring is a circular ring structure, the diameter of the circular ring is the same as that of the second movable ring, and the inner diameter of the circular ring is the same as that of the second bent portion.

In the bearing device of any one of the embodiments, the housing has a third opening, and the third opening is used for inputting the fluid under pressure into the first space.

A mechanical seal and thrust bearing combined bearing device is used for reducing axial load of a rotating shaft and comprises a thrust bearing, a shell, a first movable ring, a first static seal assembly and a second static seal assembly.

The thrust bearing is sleeved on the rotating shaft.

The housing encloses a first space for storing fluid under pressure. The housing and the thrust bearing are arranged at intervals. The housing has a first opening and a second opening disposed opposite to each other. The first opening and the second opening are used for penetrating through the rotating shaft. The area of the first opening is larger than the area of the second opening. The direction of the second opening pointing to the first opening is a first direction. The first direction coincides with an axial thrust direction of the thrust bearing that cancels the axial load. The first movable ring is accommodated in the first space and is fixedly sleeved on the rotating shaft. The first rotating ring is provided with a first surface and a second surface which are oppositely arranged, and the first surface is arranged close to the first opening.

The edge of the first opening is bent towards the first space and extends to the first surface to form a first bent part. The edge of the second opening faces the first space and extends to the second surface to form a second bending part. The rotation axis passes through the first bending part and the second bending part. The first static sealing assembly is accommodated in the first space and is arranged around the first bending part. One end of the first static sealing component is abutted against the inner wall of the shell. The other end of the first static seal component is abutted against the first surface. The second static sealing assembly is accommodated in the first space and is arranged around the second bending part. One end of the second static sealing component is abutted against the inner wall of the shell. The other end of the second static seal component is abutted against the third surface.

In one embodiment, the first static seal assembly includes a first static ring and a first resilient element. The first stationary ring is sleeved on the first bending part and provided with a fifth surface and a sixth surface which are opposite to each other. The fifth surface is attached to the first surface. One end of the first elastic element is fixed on the inner wall of the shell, and the other end of the first elastic element abuts against the sixth surface and is connected with the first stationary ring.

In one embodiment, the second static seal assembly includes a second static ring and a second resilient element. The second stationary ring is sleeved on the second bending part and provided with a seventh surface and an eighth surface which are opposite to each other. The seventh surface is attached to the third surface. One end of the second elastic element is fixed on the inner wall of the shell, and the other end of the second elastic element abuts against the eighth surface and is connected with the second stationary ring.

In one embodiment, the second stationary ring is a circular ring structure, the outer diameter of the circular ring is the same as the diameter of the second movable ring, and the inner diameter of the circular ring is the same as the diameter of the second bent portion.

The application provides a mechanical seal and thrust bearing combination bear device, including casing, first rotating ring, second rotating ring, first static seal subassembly and the static seal subassembly of second. The housing encloses a first space for storing fluid under pressure. The housing includes a first opening and a second opening disposed in opposition. The first static seal assembly and the second static seal assembly are received in the first space.

One end of the first static sealing component is abutted against the inner wall of the shell, and the other end of the first static sealing component is abutted against the first surface. Under the pressure of the high-pressure fluid, the first static seal assembly generates pressure on the first movable ring through the first surface. Similarly, one end of the second static sealing component abuts against the inner wall of the shell, the other end of the second static sealing component abuts against the fourth surface, and the second static sealing component generates pressure on the second movable ring through the third surface. The above-mentioned pressure effect enables to seal the first space.

After the first space is filled with high-pressure fluid, under the pressure of the high-pressure fluid, the pressure applied to the third surface and the second surface in the first direction is greater than the pressure applied to the first surface, and because the first rotating ring and the second rotating ring are fixedly arranged relative to the rotating shaft, the first rotating ring and the second rotating ring generate axial thrust on the rotating shaft in the first direction, that is, the mechanical seal and thrust bearing combined bearing device generates axial thrust on the rotating shaft in the first direction.

The first direction is in line with the thrust bearing output axial load direction. When the rotating shaft is subjected to initial axial thrust, the mechanical seal and thrust bearing combined bearing device and the thrust bearing jointly provide the axial thrust compared with the axial thrust provided by the single thrust bearing, and the working load of the thrust bearing is reduced. The mechanical seal and thrust bearing combined bearing device and the thrust bearing act in a synergistic manner, so that material fatigue of the thrust bearing under a high-load working condition due to overhigh temperature is avoided, and further, the reliability of the thrust bearing is improved.

Drawings

FIG. 1 is a schematic structural view of the combined mechanical seal and thrust bearing carrier provided in an embodiment of the present application;

FIG. 2 is a force diagram illustrating the structure of the combined mechanical seal and thrust bearing load apparatus provided in an embodiment of the present application;

FIG. 3 is a schematic structural view of the combined mechanical seal and thrust bearing carrier provided in another embodiment of the present application;

FIG. 4 is a force diagram illustrating the structure of the combined mechanical seal and thrust bearing load bearing device provided in another embodiment of the present application;

FIG. 5 is a schematic structural diagram of the combined mechanical seal and thrust bearing carrier provided in another embodiment of the present application.

Reference numerals:

mechanical seal and thrust bearing combination load bearing device 10

Thrust bearing 100

Rotating shaft 101

Housing 20

First space 210

The first bending part 220

The second bending part 230

First opening 201

Second opening 202

Third opening 203

First rotating ring 30

First surface 301

Second surface 302

Platform 302

Second rotating ring 40

Third surface 401

Fourth surface 402

First static seal assembly 510

First stationary ring 511

First elastic element 512

Fifth surface 501

Sixth surface 502

Seventh surface 503

Eighth surface 504

Second static seal assembly 520

Second stationary ring 521

Second elastic element 522

First direction a

Second direction b

Detailed Description

In order to make the aforementioned objects, features and advantages of the present application more comprehensible, embodiments accompanying the present application are described in detail below with reference to the accompanying drawings. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present application. This application is capable of embodiments in many different forms than those described herein and those skilled in the art will be able to make similar modifications without departing from the spirit of the application and it is therefore not intended to be limited to the embodiments disclosed below.

The numbering of the components as such, e.g., "first", "second", etc., is used herein only to distinguish the objects as described, and does not have any sequential or technical meaning. The term "connected" and "coupled" when used in this application, unless otherwise indicated, includes both direct and indirect connections (couplings). In the description of the present application, it is to be understood that the terms "upper", "lower", "front", "rear", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", "clockwise", "counterclockwise", and the like, indicate orientations or positional relationships based on those shown in the drawings, and are used only for convenience in describing the present application and for simplicity in description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, are not to be considered as limiting the present application.

In this application, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may be directly contacting the first and second features or indirectly contacting the first and second features through intervening media. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

Referring to fig. 1, the present embodiment provides a mechanical seal and thrust bearing combination bearing assembly 10 for reducing axial loading of a rotating shaft 101. The combined mechanical seal and thrust bearing carrier 10 includes a thrust bearing 100, a housing 20, a first dynamic ring 30, a second dynamic ring 40, a first static seal assembly 510, and a second static seal assembly 520.

The thrust bearing 100 is sleeved on the rotating shaft 101. The housing 20 encloses a first space 210 for storing fluid under pressure. The housing 20 is spaced apart from the thrust bearing 100. The housing 20 has a first opening 201 and a second opening 202 disposed opposite to each other. The first opening 201 and the second opening 202 are used for passing through the rotating shaft 101. The area of the first opening 201 is larger than the area of the second opening 202. The direction in which the second opening 202 is directed toward the first opening 201 is a first direction, and the first direction coincides with an axial thrust direction in which the axial load force is cancelled by the thrust bearing 100.

The first rotating ring 30 is accommodated in the first space 210 and is fixedly sleeved on the rotating shaft 101. The first rotating ring 30 has a first surface 301 and a second surface 302 which are oppositely arranged, and the first surface 301 is arranged near the first opening 201.

The second rotating ring 40 is accommodated in the first space 210, and is fixedly sleeved on the rotating shaft 101 and located on a side of the first rotating ring 30 away from the first opening 201. The second rotating ring 40 has a third surface 401 and a fourth surface 402 opposite to each other. The fourth surface 402 is disposed adjacent to the second surface 302. The diameter of the first rotating ring 30 is larger than the diameter of the second rotating ring 40.

The edge of the first opening 201 is bent toward the first space 210 and extends to the first surface 301 to form a first bent portion 220. The edge of the second opening 202 extends to the first space 210 and the third surface 401 to form a second bending portion 230. The rotating shaft 101 passes through the first bending portion 220 and the second bending portion 230, so that a part of the surface of the first rotating ring 30 and the second rotating ring 40 is enclosed in the first space 210, and a part of the surface is exposed outside the first space 210.

The first static seal component 510 is received in the first space 210 and disposed around the first bending portion 220. One end of the first static seal component 510 abuts against the inner wall of the housing 20. The other end of the first static seal component 510 abuts against the first surface 301, so as to seal a gap between the first bending portion 220 and the first surface 301, and reduce the leakage amount of the pressurized fluid.

The second static seal component 520 is received in the first space 210 and disposed around the second bending portion 230. One end of the second static sealing component 520 abuts against the inner wall of the housing 20, and the other end of the second static sealing component 520 abuts against the third surface 401, so as to seal a gap between the second bending portion 230 and the third surface 401, further reduce the leakage amount of the pressurized gas, and ensure the stability of the pressurized fluid pressure in the first space 210.

The rotating shaft 101 is provided in a motor or other rotating machine. The rotating shaft 101 is subjected to an initial axial thrust. The direction of the initial thrust is a second direction b. The second direction b is opposite to the first direction a. In order to avoid axial play of the rotating shaft 101 due to the initial axial thrust, a thrust bearing is required to counteract the initial axial thrust. The thrust bearing 100 has a limit load, and when the load of the thrust bearing 100 exceeds the limit load, the thrust bearing 100 may have a temperature increase, resulting in material fatigue. Therefore, the mechanical seal and thrust bearing combined bearing device 10 and the thrust bearing 100 cooperate to avoid the situation of material fatigue caused by overhigh temperature due to the high axial load bearing of the thrust bearing 100.

The pressurized fluid is pressurized gas, pressurized liquid or pressurized gas-liquid mixture. The pressure of the pressurized fluid is greater than the pressure outside the housing 20.

The combined mechanical seal and thrust bearing carrier 10 provided herein includes the thrust bearing 100, the housing 20, the first dynamic ring 30, the second dynamic ring 40, the first static seal assembly 510, and the second static seal assembly 520. The housing 20 encloses a first space 210 for storing fluid under pressure. The housing 20 has a first opening 201 and a second opening 202 disposed opposite to each other. One end of the first static seal component 510 abuts against the inner wall of the housing 20.

The other end of the first static seal component 510 abuts against the first surface 301. Under the pressure of the high-pressure fluid, the first static seal assembly 510 generates a pressure on the first moving ring 30 through the first surface 301. Similarly, one end of the second static seal component 520 abuts against the inner wall of the housing 20, and the other end of the second static seal component 520 abuts against the third surface 401. The second static seal assembly 520 generates pressure against the second rotating ring 40 through the third surface 401. The above-mentioned pressure action can seal the first space 210.

Referring to fig. 2, after the first space 210 is filled with the high-pressure fluid, the third surface 401 is pressed by the second static seal component 520 and the first surface 301 is pressed by the first static seal component 510 under the pressure of the high-pressure fluid. The third surface 401 and the second surface 302 are subjected to a pressure (F1+ F2) towards the first direction that is greater than the pressure F3 to which the first surface 301 is subjected. Since the first rotating ring 30 and the second rotating ring 40 are fixedly arranged relative to the rotating shaft, the first rotating ring 30 and the second rotating ring 40 generate an axial thrust Fa along the first direction a to the rotating shaft 101, that is, the mechanical seal and thrust bearing assembly 10 generates an axial thrust Fa along the first direction a to the rotating shaft 101.

The first direction a coincides with the direction in which the thrust bearing 100 outputs an axial load. When the rotating shaft 101 is subjected to an initial axial thrust Fb, the combined mechanical seal and thrust bearing carrier 10 and the thrust bearing 100 together provide an axial thrust to counteract the axial thrust Fb, i.e., Fa + Fc ═ Fb, as compared to the axial thrust Fc provided by the thrust bearing 100 alone, thereby reducing the operating load of the thrust bearing 100. The mechanical seal and thrust bearing combined bearing device 10 and the thrust bearing 100 cooperate to avoid material fatigue of the thrust bearing 100 caused by overhigh temperature under a high-load working condition, and further improve the reliability of the thrust bearing 100.

When a larger Fa is required, the pressure of the pressurized fluid can be increased, so that the difference between (F1+ F2) and F3 is increased until the design requirement is met.

The pressurized fluid is pressurized gas, pressurized liquid or pressurized gas-liquid mixture. The pressure of the fluid under pressure is greater than the pressure outside the first space 210.

Since the area of the first opening 201 is larger than the area of the second opening 202. The area of the third surface 401 exposed outside the first space 210 is smaller than the area of the first surface 301 outside the first space 210. The sum of the pressing area of the second static seal assembly 520 ring and the pressing area of the second surface 302 is greater than the pressing area of the first static seal assembly 510.

Since the pressure of the pressurized gas in the first space 210 is the same everywhere, the larger the force-bearing area is, the larger the force is. The first moving ring 30 and the second moving ring 40 surround the first space 210, and the resultant force (F1+ F2) applied to the surface close to the second opening 202 is greater than the surface pressure F3 of the first moving ring 30 surrounding the first space 210 and close to the first opening 201. In turn, the first and second moving ring 30, 40 surfaces create a pressure difference Fa along the first direction a, where Fa ═ F1+ F2-F3. The pressure differential acts on the first rotating ring 30 and the second rotating ring 40. Because the first rotating ring 30 and the second rotating ring 40 are fixedly connected with the rotating shaft 101, the first rotating ring 30 and the second rotating ring 40 generate an axial thrust Fa along the first direction a to the rotating shaft 101, that is, the mechanical seal and thrust bearing assembly 10 generates an axial thrust Fa along the first direction a to the rotating shaft 101.

In one embodiment, the shape of the housing 20 may be a regular shape such as a rectangular parallelepiped or a cylinder, or may be an irregular shape. The housing 20 does not rotate with the rotating shaft 101. The housing 20 is fixed in the outer structure, and the position of the mechanical seal and thrust bearing combination bearing device 10 is fixed when the mechanical seal and thrust bearing combination bearing device operates.

In one embodiment, the second rotating ring 40 and the first rotating ring 30 rotate together with the rotating shaft 101. The diameter of the first rotating ring 30 is larger than the diameter of the second rotating ring 40. The second rotating ring 40 and the first rotating ring 30 form a stepped structure, so that the thickness of the first rotating ring 30 along the first direction a is reduced, and the overall weight of the mechanical seal and thrust bearing combined bearing device 10 is reduced.

In one embodiment, the projection of the second rotating ring 40 to the second surface 302 surrounds the second surface 302, so that the material is saved and the replacement is facilitated.

In one embodiment, the first rotating ring 30 and the second rotating ring 40 may be the same or different in shape. The shapes of the first movable ring 30 and the second movable ring 40 may be regular three-dimensional structures such as a rectangular parallelepiped, a cube, or a cylinder, and may also be irregular three-dimensional structures.

In one embodiment, the first rotating ring 30 and the second rotating ring 40 are cylinders, and the circular surfaces of the cylinders are perpendicular to the first direction a, so that the cylinders are highly symmetrical, and resources are saved.

The combined mechanical seal and thrust bearing carrier 10 may include a plurality of rotating rings, and the rotating rings are fixedly connected to the rotating shaft 101. The plurality of rotating rings may be arranged in a stepped shaft configuration to reduce overall structural mass.

In one embodiment, the first static seal assembly 510 includes a first static ring 511 and a first resilient element 512. The first stationary ring 511 is sleeved on the first bending portion 220, and the first stationary ring 511 has a fifth surface 501 and a sixth surface 502 opposite to each other. The fifth surface 501 is attached to the first surface 301. One end of the first elastic element 512 is fixed to the inner wall of the housing 20, and the other end of the first elastic element 512 abuts against the sixth surface 502 and is connected to the first stationary ring 511.

The first stationary ring 511 is fixedly connected to the first elastic member 512 and contacts with the surface of the first movable ring 30. The first elastic element 512 pushes the first stationary ring 511 to fit the first surface 301. When the first rotating ring 30 rotates, an air film with a certain rigidity is formed between the first stationary ring 511 and the first rotating ring 30, so as to seal a gap between the first rotating ring 30 and the first bending portion 220, protect the first rotating ring 30, and avoid abrasion of the first rotating ring 30.

In one embodiment, the first elastic element 512 is a spring. The spring has a gap into which the fluid under pressure enters and acts on the surface of the first resilient element 512 of the first static seal assembly. The pressurized fluid applies a pressure to the first stationary ring 511 that is perpendicular to the sixth surface 502, i.e., F3. The first stationary ring 511 transmits F3 to the surface of the first moving ring 30.

In one embodiment, the second static seal assembly 520 includes a second static ring 521 and a second resilient member 522. The second stationary ring 521 is sleeved on the second bending portion 230, and the second stationary ring 521 has a seventh surface 503 and an eighth surface 504 which are opposite to each other. The seventh surface 503 is attached to the third surface 401. One end of the second elastic element 522 is fixed to the inner wall of the housing 20, and the other end of the second elastic element 522 abuts against the eighth surface 504 and is connected to the second stationary ring 521.

The second stationary ring 521 is fixedly connected to the second elastic element 522 and contacts with the surface of the second movable ring 40. The second elastic element 522 pushes the second stationary ring 521 to fit the third surface 401. When the second rotating ring 40 rotates, an air film with a certain rigidity is formed between the second stationary ring 521 and the second rotating ring 40, so as to seal a gap between the second rotating ring 40 and the second bending portion 230, protect the second rotating ring 40, avoid abrasion of the second rotating ring 40, and ensure normal rotation of the rotating shaft 101.

In one embodiment, the second resilient element 522 is a spring. The spring has a gap into which the pressurized fluid enters and acts on the surface of the second stationary ring 521 adjacent to the second elastic element 522. The pressurized fluid applies a pressure perpendicular to the eighth surface 504 to the second stationary ring 521, which is F1. The second stationary ring 521 transmits F1 to the surface of the second moving ring 40.

In one embodiment, the first elastic elements 512 are disposed at intervals along the first bending portion 220, so as to apply a uniform force and increase the reliability of the overall structure.

In one embodiment, the first bent portion 220 is a circular ring structure, the outer diameter of the first stationary ring 511 is the same as the outer diameter of the first movable ring 30, and the inner diameter of the first stationary ring 511 is the same as the outer diameter of the first bent portion 220, so as to ensure that the gap between the first movable ring 30 and the first bent portion 220 is sealed, and improve the air tightness of the first space 210.

In one embodiment, the second stationary ring 521 has a circular ring structure, the diameter of the circular ring is the same as the diameter of the second movable ring 40, and the inner diameter of the circular ring is the same as the diameter of the second bent portion 230, so as to ensure that the gap between the second movable ring 40 and the second bent portion 230 is sealed, and further improve the air tightness of the first space 210.

In the combined bearing device of the mechanical seal and the thrust bearing described in any of the above embodiments, the housing 20 defines a third opening 203, and the third opening 203 is used for inputting the fluid under pressure into the first space 210. The fluid flow of the third opening 203 is adjustable to ensure stability of the pressure in the first space 210. The fluid pressure is adjustable, and the mechanical seal and thrust bearing combined bearing device 10 is guaranteed to provide axial thrust with different magnitudes.

Referring also to fig. 3, the present application provides a combined mechanical seal and thrust bearing carrier 10 for reducing axial loading of a rotating shaft 101, the combined mechanical seal and thrust bearing carrier 10 including a thrust bearing 100, a housing 20, a first rotating ring 30, a first stationary seal assembly 510, and a second stationary seal assembly 520.

The thrust bearing 100 is sleeved on the rotating shaft 101. The housing 20 encloses a first space 210 for storing fluid under pressure. The housing 20 is spaced apart from the thrust bearing 100. The housing 20 has a first opening 201 and a second opening 202 disposed opposite to each other. The first opening 201 and the second opening 202 are used for passing through the rotating shaft 101. The area of the first opening 201 is larger than the area of the second opening 202. The direction in which the second opening 202 points to the first opening 201 is a first direction. The first direction coincides with an axial thrust direction that cancels the axial load generated by the thrust bearing 100.

The first rotating ring 30 is accommodated in the first space 210 and is fixedly sleeved on the rotating shaft 101. The first rotating ring 30 has a first surface 301 and a second surface 302 which are oppositely arranged, and the first surface 301 is arranged near the first opening 201.

The edge of the first opening 201 is bent toward the first space 210 and extends to the first surface 301 to form a first bent portion 220. The edge of the second opening 202 extends to the first space 210 and the second surface 302 to form a second bending portion 230. The rotating shaft 101 passes through the first bending portion 220 and the second bending portion 230, so that a part of the surface of the first rotating ring 30 is enclosed in the first space 210, and a part of the surface is exposed outside the first space 210.

The first static seal component 510 is received in the first space 210 and disposed around the first bending portion 220. One end of the first static seal component 510 abuts against the inner wall of the housing 20. The other end of the first static seal component 510 abuts against the first surface 301, so as to seal a gap between the first bending portion 220 and the first surface 301, and reduce the leakage amount of the high-pressure gas.

The second static seal component 520 is received in the first space 210 and disposed around the second bending portion 230. One end of the second static seal component 520 abuts against the inner wall of the housing 20. The other end of the second static sealing element 520 abuts against the second surface 302, and is used for sealing a gap between the second bending portion 230 and the second surface 302, and further reducing the leakage amount of high-pressure gas, so as to ensure the stability of the pressure of the pressurized fluid in the first space 210.

The present application provides another combined mechanical seal and thrust bearing carrier 10, including the thrust bearing 100, the housing 20, the first dynamic ring 30, the first static seal assembly 510, and the second static seal assembly 520. The housing 20 encloses a first space 210 for storing fluid under pressure. The housing 20 has a first opening 201 and a second opening 202 disposed opposite to each other. One end of the first static seal component 510 abuts against the inner wall of the housing 20.

The other end of the first static seal component 510 abuts against the first surface 301. Under the pressure of the high-pressure fluid, the first static seal assembly 510 generates a pressure on the first moving ring 30 through the first surface 301. Similarly, one end of the second static seal component 520 abuts against the inner wall of the housing 20, and the other end of the second static seal component 520 abuts against the second surface 302. The second static seal assembly 520 generates pressure against the first moving ring 30 via the second surface 302. The above-mentioned pressure action can seal the first space 210.

Referring to fig. 4, after the first space 210 is filled with the high-pressure fluid, the second static seal component 520 presses the second surface 302 and the first static seal component 510 presses the first surface 301 under the pressure of the high-pressure fluid. The second surface 302 is subjected to a pressure F1 directed towards the first direction that is greater than the pressure F2 that the first surface 301 is subjected to. Since the first rotating ring 30 is fixedly arranged relative to the rotating shaft, the first rotating ring 30 generates an axial thrust Fa along the first direction a to the rotating shaft 101, i.e. the mechanical seal and thrust bearing combination bearing device 10 generates an axial thrust Fa along the first direction a to the rotating shaft 101.

The first direction a coincides with the direction in which the thrust bearing 100 outputs an axial load. When the rotating shaft 101 is subjected to an initial axial thrust Fb, the combined mechanical seal and thrust bearing carrier 10 and the thrust bearing 100 together provide an axial thrust to counteract the axial thrust Fb, i.e., Fa + Fc ═ Fb, as compared to the axial thrust Fc provided by the thrust bearing 100 alone, thereby reducing the operating load of the thrust bearing 100. The mechanical seal and thrust bearing combined bearing device 10 and the thrust bearing 100 cooperate to avoid material fatigue of the thrust bearing 100 caused by overhigh temperature under a high-load working condition, and further improve the reliability of the thrust bearing 100.

Since the area of the first opening 201 is larger than that of the second opening 202, the area of the second surface 302 exposed outside the first space 210 is smaller than that of the first surface 301 outside the first space 210. The pressing area of the second static seal assembly 520 is larger than that of the first static seal assembly 510 to the first moving ring 30.

Since the pressure of the pressurized gas in the first space 210 is the same everywhere, the larger the force-bearing area is, the larger the force is. The first rotating ring 30 surrounds the first space 210, and the surface close to the second opening 202 receives a force F1 greater than the force F2 received by the surface close to the first opening 201 surrounded by the second rotating ring 40. In turn, the first moving ring 30 surface generates a pressure difference Fa along the first direction a, where Fa ═ F1-F2. The pressure differential acts on the first rotating ring 30. Because the first rotating ring 30 is fixedly connected with the rotating shaft 101, the first rotating ring 30 generates an axial thrust Fa along the first direction a to the rotating shaft 101, that is, the mechanical seal and thrust bearing combination bearing device 10 generates an axial thrust Fa along the first direction a to the rotating shaft 101.

When a larger Fa is required, the pressure of the pressurized fluid can be increased, so that the difference between F1 and F2 is increased until the design requirement is met.

In one embodiment, the first static seal assembly 510 includes a first static ring 511 and a first resilient element 512. The first stationary ring 511 is sleeved on the first bending portion 220, and the first stationary ring 511 has a fifth surface 501 and a sixth surface 502 opposite to each other. The fifth surface 501 is attached to the first surface 301. One end of the first elastic element 512 is fixed to the inner wall of the housing 20, and the other end of the first elastic element 512 abuts against the sixth surface 502 and is connected to the first stationary ring 511.

In one embodiment, the first elastic element 512 is a spring. The spring has a slit into which the fluid under pressure enters and acts on the surface of the first stationary ring 511 adjacent to the first elastic element 512. The pressurized fluid applies a pressure to the first stationary ring 511 that is perpendicular to the sixth surface 502, i.e., F2. The first stationary ring 511 transmits F2 to the surface of the first moving ring 30.

The first stationary ring 511 is fixedly connected to the first elastic member 512 and contacts with the surface of the first movable ring 30. When the first rotating ring 30 rotates, an air film with a certain rigidity is formed between the first stationary ring 511 and the first rotating ring 30, so as to seal a gap between the first rotating ring 30 and the first bending portion 220, protect the first rotating ring 30, and avoid abrasion.

In one embodiment, the second static seal assembly 520 includes a second static ring 521 and a second resilient member 522. The second stationary ring 521 is sleeved on the second bending portion 230, and the second stationary ring 521 has a seventh surface 503 and an eighth surface 504 which are opposite to each other. The seventh surface 503 is attached to the second surface 302. One end of the second elastic element 522 is fixed to the inner wall of the housing 20, and the other end of the second elastic element 522 abuts against the eighth surface 504 and is connected to the second stationary ring 521.

The second stationary ring 521 is fixedly connected to the second elastic element 522 and contacts with the surface of the first moving ring 30. When the first rotating ring 30 rotates, an air film with a certain rigidity is formed between the second stationary ring 521 and the first rotating ring 30, so as to seal a gap between the first rotating ring 30 and the second bending portion 230, protect the first rotating ring 30, and avoid abrasion.

In one embodiment, the second resilient element 522 is a spring. The spring has a gap into which the pressurized fluid enters and acts on the surface of the second stationary ring 521 adjacent to the second elastic element 522. The pressurized fluid applies a pressure perpendicular to the eighth surface 504 to the second stationary ring 521, which is F1. The second stationary ring 521 transmits F1 to the surface of the first moving ring 30.

In one embodiment, the second stationary ring 521 is a circular ring structure, the outer diameter of the circular ring is the same as the diameter of the first movable ring 30, and the inner diameter of the circular ring is the same as the diameter of the second bent portion 230, so as to seal the gap between the first movable ring 30 and the second bent portion 230, protect the first movable ring 30, and ensure the normal rotation of the rotating shaft 101.

Referring to fig. 5, in an embodiment, the second stationary ring 521 is a circular ring structure, an outer diameter of the circular ring is smaller than a diameter of the first moving ring 30, and an inner diameter of the circular ring is the same as the diameter of the second bending portion 230, so as to seal a gap between the first moving ring 30 and the second bending portion 230, and improve sealing performance.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-described examples merely represent several embodiments of the present application and are not to be construed as limiting the scope of the claims. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the concept of the present application, which falls within the scope of protection of the present application. Therefore, the protection scope of the present patent shall be subject to the appended claims.

Claims (11)

1. A combined mechanical seal and thrust bearing load bearing device for reducing axial loading of a rotating shaft (101), characterized in that said combined mechanical seal and thrust bearing load bearing device (10) comprises:

a thrust bearing (100) sleeved on the rotating shaft (101);

a housing (20) enclosing to form a first space (210) for storing fluid under pressure, the housing (20) being spaced apart from the thrust bearing (100), the housing (20) having a first opening (201) and a second opening (202) opposite to each other, the first opening (201) and the second opening (202) being used for passing through the rotating shaft (101), the area of the first opening (201) being larger than that of the second opening (202), the direction of the second opening (202) pointing to the first opening (201) being a first direction, and the first direction being consistent with an axial thrust direction generated by the thrust bearing (100) for counteracting an axial load force;

the first movable ring (30) is accommodated in the first space (210) and is used for being fixedly sleeved on the rotating shaft (101), the first movable ring (30) is provided with a first surface (301) and a second surface (302) which are oppositely arranged, and the first surface (301) is arranged close to the first opening (201);

the second movable ring (40) is accommodated in the first space (210), is fixedly sleeved on the rotating shaft (101), and is positioned on one side, away from the first opening (201), of the first movable ring (30), the second movable ring (40) is provided with a third surface (401) and a fourth surface (402) which are opposite, the fourth surface (402) is attached to the second surface (302), and the diameter of the first movable ring (30) is larger than that of the second movable ring (40);

the edge of the first opening (201) is bent towards the first space (210) and extends to the first surface (301) to form a first bent part (220), the edge of the second opening (202) is bent towards the first space (210) and extends to a third surface (401) to form a second bent part (230), and the rotating shaft (101) penetrates through the first bent part (220) and the second bent part (230);

the first static sealing component (510) is accommodated in the first space (210) and arranged around the first bending part (220), one end of the first static sealing component (510) abuts against the inner wall of the shell (20), and the other end of the first static sealing component (510) abuts against the first surface (301);

and the second static sealing component (520) is accommodated in the first space (210) and arranged around the second bending part (230), one end of the second static sealing component (520) is abutted against the inner wall of the shell (20), and the other end of the second static sealing component (520) is abutted against the third surface (401).

2. The combined mechanical seal and thrust bearing carrier device of claim 1, wherein said first static seal assembly (510) comprises:

the first stationary ring (511) is sleeved on the first bending part (220), the first stationary ring (511) is provided with a fifth surface (501) and a sixth surface (502) which are opposite to each other, and the fifth surface (501) is attached to the first surface (301);

one end of the first elastic element (512) is fixed on the inner wall of the shell (20), and the other end of the first elastic element (512) abuts against the sixth surface (502) and is connected with the first static ring (511).

3. The combined mechanical seal and thrust bearing carrier device of claim 2, wherein said second static seal assembly (520) includes:

the second stationary ring (521) is sleeved on the second bending part (230), the second stationary ring (521) is provided with a seventh surface (503) and an eighth surface (504) which are opposite, and the seventh surface (503) is attached to the third surface (401);

and one end of the second elastic element (522) is fixed on the inner wall of the shell (20), and the other end of the second elastic element (522) abuts against the eighth surface (504) and is connected with the second static ring (521).

4. The mechanical seal and thrust bearing combination load bearing device of claim 2, wherein said first resilient element (512) is a plurality of resilient elements circumferentially spaced along said first bend (220).

5. The mechanical seal and thrust bearing combined bearing device of claim 2, wherein the first bent portion (220) is a circular ring structure, the outer diameter of the first stationary ring (511) is the same as the outer diameter of the first movable ring (30), and the inner diameter of the first stationary ring (511) is the same as the diameter of the first bent portion (220).

6. The mechanical seal and thrust bearing combination load bearing device of claim 3, wherein said second stationary ring (521) is a circular ring structure, the diameter of said circular ring is the same as the diameter of said second movable ring (40), and the inner diameter of said circular ring is the same as the diameter of said second bent portion (230).

7. The combined mechanical seal and thrust bearing carrier device according to any one of claims 1 to 6, characterized in that said housing (20) is provided with a third opening (203), said third opening (203) being adapted to feed said fluid under pressure into said first space (210).

8. A combined mechanical seal and thrust bearing load bearing device for reducing axial loading of a rotating shaft (101), characterized in that said combined mechanical seal and thrust bearing load bearing device (10) comprises:

a thrust bearing (100) sleeved on the rotating shaft (101); a housing (20) enclosing to form a first space (210) for storing pressurized fluid, wherein the housing (20) is arranged at a distance from the thrust bearing (100), the housing (20) has a first opening (201) and a second opening (202) which are arranged oppositely, the first opening (201) and the second opening (202) are used for penetrating through the rotating shaft (101), the area of the first opening (201) is larger than that of the second opening (202), the direction of the second opening (202) pointing to the first opening (201) is a first direction, and the first direction is consistent with the axial thrust direction generated by the thrust bearing (100) for counteracting the axial load;

the first movable ring (30) is accommodated in the first space (210) and is used for being fixedly sleeved on the rotating shaft (101), the first movable ring (30) is provided with a first surface (301) and a second surface (302) which are oppositely arranged, and the first surface (301) is arranged close to the first opening (201);

the edge of the first opening (201) is bent towards the first space (210) and extends to the first surface (301) to form a first bent part (220), the edge of the second opening (202) is bent towards the first space (210) and extends to the second surface (302) to form a second bent part (230), and the rotating shaft (101) passes through the first bent part (220) and the second bent part (230);

the first static sealing component (510) is accommodated in the first space (210) and arranged around the first bending part (220), one end of the first static sealing component (510) abuts against the inner wall of the shell (20), and the other end of the first static sealing component (510) abuts against the first surface (301);

and the second static sealing component (520) is accommodated in the first space (210) and arranged around the second bending part (230), one end of the second static sealing component (520) is abutted against the inner wall of the shell (20), and the other end of the second static sealing component (520) is abutted against the second surface (302).

9. The combined mechanical seal and thrust bearing carrier device of claim 8, wherein said first static seal assembly (510) comprises:

the first stationary ring (511) is sleeved on the first bending part (220), the first stationary ring (511) is provided with a fifth surface (501) and a sixth surface (502) which are opposite to each other, and the fifth surface (501) is attached to the first surface (301);

one end of the first elastic element (512) is fixed on the inner wall of the shell (20), and the other end of the first elastic element (512) abuts against the sixth surface (502) and is connected with the first static ring (511).

10. The combined mechanical seal and thrust bearing carrier device of claim 9, wherein said second static seal assembly (520) includes:

the second stationary ring (521) is sleeved on the second bending part (230), the second stationary ring (521) is provided with a seventh surface (503) and an eighth surface (504) which are opposite, and the seventh surface (503) is attached to the second surface (302);

and one end of the second elastic element (522) is fixed on the inner wall of the shell (20), and the other end of the second elastic element (522) abuts against the eighth surface (504) and is connected with the second static ring (521).

11. The mechanical seal and thrust bearing combination load bearing device of claim 10, wherein said second stationary ring (521) is a circular ring structure, said circular ring having an outer diameter equal to a diameter of said first movable ring (30), and said circular ring having an inner diameter equal to a diameter of said second bent portion (230).

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