阅读说明：本技术 密封圈 (Sealing ring ) 是由 李定 刘鑫 于 2020-06-30 设计创作，主要内容包括：本发明涉及一种密封圈,所述密封圈具有由弹性体制成的密封唇(6),密封唇(6)用于可滑动地抵靠旋转部件,其中,密封唇(6)包括分别朝向轴向两侧的第一密封斜面(3)和第二密封斜面(4),其中,第一密封斜面(3)相比第二密封斜面(4)更平缓,其中,在第一密封斜面(3)和/或第二密封斜面处(4)处构造有呈网状的凸棱结构(5)。(The invention relates to a sealing ring, comprising a sealing lip (6) made of an elastomer, wherein the sealing lip (6) is used for slidably abutting against a rotating component, wherein the sealing lip (6) comprises a first sealing inclined surface (3) and a second sealing inclined surface (4) which face to two axial sides respectively, wherein the first sealing inclined surface (3) is more gentle than the second sealing inclined surface (4), and a reticular rib structure (5) is formed at the first sealing inclined surface (3) and/or the second sealing inclined surface (4).)

1. Sealing ring with a sealing lip (6) made of an elastomer, the sealing lip (6) being intended to slidably abut against a rotating component, wherein the sealing lip (6) comprises a first sealing bevel (3) and a second sealing bevel (4) towards the axial sides, respectively, characterized in that a web-like ridge structure (5) is configured at the first sealing bevel (3) and/or at the second sealing bevel (4).

2. A sealing ring according to claim 1, wherein the first sealing bevel (3) is more gradual than the second sealing bevel (4), the bead structure (5) being configured at the first sealing bevel (3).

3. A sealing ring according to claim 1 or 2, wherein the bead structure (5) is circumferentially configured at the sealing lip (6).

4. A sealing ring according to claim 3, wherein the bead structure (5) is arranged such that at any circumferential position of the sealing lip (6) there is at least one closed grid.

5. A sealing ring according to claim 1, wherein the bead structure (5) extends axially from the lip of the sealing lip (6) towards the respective axial side.

6. A sealing ring according to claim 1, wherein the individual ridges configuring the ridge structure (5) are linear, polygonal and/or curved.

7. The sealing ring according to claim 1, wherein the sealing ring further comprises a skeleton (1) for supporting the sealing ring.

8. The seal ring as claimed in claim 1, wherein the seal ring further comprises an additional sealing lip.

9. The seal ring according to claim 1 or 8, wherein the seal ring further comprises a spring ring (7) to press the sealing lip of the seal ring against the rotating component.

Technical Field

The invention relates to a sealing technology. The invention relates in particular to a sealing ring, in particular a dynamic sealing ring.

Background

Lip type sealing rings for rotating shafts have been widely used for sealing rotating parts of various kinds of mechanical equipment. In order to improve the sealing performance of the sealing ring, besides adopting proper materials and precise dimensions, a fluid-dynamic oil return structure can be arranged at the sealing position. For example, various structures of rib-like oil return lines can be formed on the sealing portion, particularly on the air side of the sealing lip, by various groove structures provided on the die. These return lines enhance the "pumping effect" which facilitates the return of fluid leaking from the fluid side to the air side of the seal to the fluid side, especially at high rotation speeds, to ensure a sealing action. Such lip seals are also suitable for rotating shafts with a two-way rotation regime, the design of the corresponding bead-shaped return line being known from prior art solutions.

For example, in U.S. Pat. No. 3,501,155, a seal for a bidirectionally rotating rotary shaft is disclosed, which is arranged between a housing and a shaft rotating relative to the housing, is mounted on the housing and has a radially inwardly projecting sealing lip which contacts the rotary shaft in its circumferential direction and which establishes a seal between an oil side and an air side for preventing oil leakage, wherein a row of circumferentially arranged ribs is provided on the inclined surface of the sealing lip facing the oil side and a row of circumferentially arranged ribs is also formed on the inclined surface facing the air side, the two rows of ribs contacting the rotary shaft and being respectively inclined transversely in different directions relative to the axis of rotation of the rotary shaft. When the rotary shaft rotates in one of the two rotational directions, one of the two rows of ribs generates a pumping force toward the seal lip to pump oil leaking to the air side back to the oil side, respectively.

Another seal for a rotating shaft rotating in two directions is disclosed, for example, in US 6,729,624B 1, which provides, on the slope of its sealing lip facing the oil side, two circumferentially spaced-apart two-way ribs, each comprising two ribs angled between them and inclined transversely in different directions with respect to the axis of rotation of the rotating shaft.

However, in the above-described design, the ribs arranged in two directions always act in opposition, i.e. when the axis of rotation is rotated in one direction, one part of the ribs is used to provide the pumping force from the air side towards the oil side to reduce leakage, while the other part of the ribs provides the pumping force in a completely different direction. Another part of the ribs will in this case lead to oil leakage.

Disclosure of Invention

Therefore, an object of the present invention is to provide a seal ring with good sealing efficiency, which is suitable for dynamically sealing a rotating shaft with bidirectional rotation.

The above object is achieved by a sealing ring having a sealing lip made of an elastomer for sliding contact against a rotating component, wherein the sealing lip comprises a first sealing bevel and a second sealing bevel facing the two axial sides, respectively, wherein a web-shaped rib structure is formed on the first sealing bevel and/or the second sealing bevel.

It is within the scope of the present disclosure that the seal ring may be particularly useful for dynamically sealing rotating components. The center axis of the sealing ring coincides with the axis of rotation of the rotating part. Herein, unless otherwise stated, the terms "axial", "radial" and "circumferential" are based on the central axis of the seal ring, i.e. the axis of rotation of the rotating component.

Preferably, the sealing ring is arranged between a component, such as a housing, and a rotating part which can rotate relative to the component. The sealing ring is preferably fixed directly or indirectly to the above-mentioned component, for example the housing, so that when the rotating part rotates, the sealing ring rotates relative to the rotating part together with the component. The rotating part can be a shaft or a shaft-like section of a component. Alternatively, the rotating part can also be a further component, for example a flinger or the like, which is fixed to the shaft or the shaft-like section of the part.

Within the scope of this document, the sealing lip of the sealing ring, in particular the sealing lip serving as the main lip, can bear slidingly against the rotating component, so that a dynamic seal is formed between the air side and the fluid side, i.e. a space is dynamically spaced apart which can accommodate a fluid chamber with fluid, for example oil, and a fluid with no fluid or only a small amount of leakage. Here, the elastic body constituting the seal lip is preferably rubber. Advantageously, the location of the sealing contact of the sealing lip, in particular the sealing lip serving as the main lip, with the rotating component can be formed on the outer circumferential surface of the rotating component, where the sealing lip bears substantially radially against the rotating component. Alternatively, the sealing contact point of the sealing lip, in particular the sealing lip serving as the main lip, with the rotating component can be formed at an axial end face of the rotating component, where the sealing lip at least partially axially abuts against the rotating component.

Here, the web-like rib structure is designed like a fish scale pattern. The reticular rib structure is formed by a plurality of ribs which are arranged in an intersecting way. The rib is preferably a rib-like structure which is integrally formed on the elastomer, in particular the sealing lip. In one embodiment, the fluid blocked by the sealing lip is oil, and the rib now forms a return line.

In this case, a plurality of cells surrounded or enclosed by ribs is formed by the rib structure in the form of a mesh. When the sealing ring rotates, in particular at high speed, relative to the rotating component, the fluid flowing from the fluid side of the sealing lip to the air side can form turbulences in the individual mesh regions, making it difficult for the fluid to continue to flow toward the air side, thus advantageously blocking leakage of at least part of the fluid. The web-like bead structure can be arranged in particular independently of the direction of rotation of the relative rotational movement, so that the web-like bead structure can advantageously convey the fluid to the fluid side, in particular in both directions of rotation, and can thus effectively reduce the leakage of fluid in any operating mode of the rotating component with any direction of rotation. Furthermore, a sealing ring constructed in this way can have a long service life.

Particularly preferably, the first sealing slope is more gradual than the second sealing slope, and the reticulated rib structure is configured at the first sealing slope. In particular, the sealing lip has a first sealing bevel facing the air side and a second sealing bevel facing the fluid side, wherein the first sealing bevel has a smaller angle relative to the rotating component than the second sealing bevel. It is thereby possible to cause fluid, in particular oil, which has leaked from the fluid side to the air side during dynamic processes to be pumped back to the fluid side, depending on the basic mechanism of the pumping effect. The arrangement of the ribs in a net shape is particularly advantageous for enhancing the pumping effect.

In a preferred embodiment, the bead structure is formed circumferentially around the sealing lip, in particular at the first sealing bevel. The rib structure here forms an annular region with a large number of webs distributed over the entire circumference of the sealing lip, in particular of the first sealing ramp, as a result of which leakage of fluid can be reduced more completely at various circumferential positions.

In a preferred embodiment, the bead structure is arranged such that at any circumferential position of the sealing lip, in particular of the first sealing bevel, there is at least one closed grid. Thereby, at each circumferential position, the fluid flowing toward the air side can form a vortex in the respective mesh, thereby effectively preventing the fluid from flowing further toward the air side.

In a preferred embodiment, the bead structure extends axially from the lip of the sealing lip towards the respective axial side. In this case, the bead formation may be disposed adjacent the lip of the sealing lip. Preferably, the web-like rib structure formed at the first sealing slope extends from the lip of the sealing lip toward the air side. When the seal ring is assembled, the seal lip is pressed against the rotating component, and the rib structures can be at least partially abutted against the rotating component to be in contact with each other, so that the return of the fluid is enhanced, and the sealing performance of the seal ring is improved.

Within the scope of this document, the shape of each fin that constitutes the fin structure is not limited. In this case, it is particularly advantageous if the individual ribs forming the rib structure are linear, zigzag and/or arc-shaped. In this case, the shape of each mesh in the rib structure in a mesh shape has a variety.

In an advantageous embodiment, the sealing ring further comprises a skeleton for supporting the sealing ring. The elastomer of the sealing ring at least partially covers the framework, thereby facilitating the fixation of the sealing ring and the dynamic sealing of the supporting elastomer against the rotating component.

Within the scope of this document, the number of sealing lips of the sealing ring is not limited. In addition to the sealing lip serving as the main lip, the sealing ring according to the invention can also have at least one further sealing lip. The additional sealing lip can be arranged here on the air side or on the fluid side relative to the main lip. The further sealing lips may establish a non-contacting seal and/or a contacting seal with the rotating component.

In an advantageous embodiment, the sealing ring further comprises a spring ring for pressing the sealing lip of the sealing ring against the rotating component. For this purpose, an annular groove for receiving the spring ring can be provided on the respective sealing lip, in particular for producing a contact seal. Therefore, the holding force of the seal lip can be enhanced, and reliable fluid seal can be realized.

In summary, a sealing ring particularly suitable for dynamically sealing a bidirectionally rotating rotary part can be provided by means of the above-described solution. The sealing ring can increase the pumping effect when the rotating component rotates in either direction of rotation by means of the web-shaped rib structure, which is formed in particular at the first sealing slope, so that the fluid can be returned to the fluid side as much as possible, in particular at the lip of the sealing lip, thereby reducing fluid leakage.

Drawings

A preferred embodiment of the invention is schematically illustrated in the following with reference to the accompanying drawings. The attached drawings are as follows:

FIG. 1 is a perspective partial cross-sectional view of a seal ring according to a preferred embodiment, an

Fig. 2 is an enlarged partial sectional view of the sealing ring according to fig. 1.

Detailed Description

Fig. 1 shows a perspective partial section through a sealing ring according to a preferred embodiment. The sealing ring can be used for dynamically sealing a rotating component with a bidirectional rotating working condition. As shown in particular in the cross-sectional area of the sealing ring in fig. 1, the sealing ring comprises an elastic sealing body 2 made of an elastomer, in particular rubber, and a carcass 1 made of metal, wherein the elastic sealing body 2 at least partially covers the carcass 1 for supporting the sealing ring.

In the present embodiment, the seal ring forms one seal lip 6 on the radially inner side by its elastic seal portion. The seal lip 6 may abut against a rotating member (not shown) substantially in the radial direction in the present embodiment, and a seal contact portion formed by the seal lip 6 and the rotating member may be formed on an outer peripheral surface of the rotating member. Here, the sealing ring also comprises a spring ring 7. An annular groove for receiving the spring ring 7 is formed on the outer circumferential surface of the sealing lip 6. The sealing lip 6 can be pressed tightly against the rotating part (not shown) by means of a spring ring 7.

The sealing lip 6 has a first sealing bevel 3 facing the air side and a second sealing bevel 4 facing the fluid side, wherein the first sealing bevel 3 is relatively gentle and the second sealing bevel 4 is relatively steep. A reticular rib structure 5 is arranged on the first sealing inclined surface 3. In the present embodiment, a rib structure 5 in a net shape is circumferentially configured at the first sealing slope 3, thereby forming an annular band provided with the rib structure 5. The bead structure 5 extends axially from the lip of the sealing lip 6 toward the air side, i.e. an axial annular boundary of the annular band is formed at the lip or lip tip of the sealing lip 6.

Fig. 2 is an enlarged partial sectional view of the sealing ring according to fig. 1, wherein the web-shaped rib structure 5 is shown enlarged. As shown in fig. 2, the rib structure 5 in a net shape is formed by a plurality of ribs arranged in an intersecting manner. The rib is a rib-like structure integrally formed by the elastic sealing body 2, specifically, the sealing lip 6. In the present embodiment, each rib is linear. In alternative embodiments, each rib may be linear, dog-leg, and/or arcuate.

The web-like rib structure 5 can be arranged such that at any circumferential position of the first sealing bevel 3 there is at least one closed grid. When the sealing ring rotates, in particular at high speed, relative to the rotating component, the fluid flowing from the fluid side of the sealing lip 6 to the air side can form turbulences (schematically indicated by arrows) in the individual mesh regions, making it difficult for the fluid to continue to flow towards the air side, thus advantageously blocking leakage of at least part of the fluid. The closed grid is particularly independent of the rotation direction of the rotating component, so that the reticular rib structure can particularly and favorably convey the fluid to the fluid side in two rotation directions, and further can effectively reduce the leakage of the fluid in the working condition of any rotation direction. Furthermore, a sealing ring constructed in this way can have a long service life.

Although possible embodiments have been described by way of example in the above description, it should be understood that numerous embodiment variations exist, still by way of combination of all technical features and embodiments that are known and that are obvious to a person skilled in the art. It should also be appreciated that the exemplary embodiment or exemplary embodiments are only examples, and are not intended to limit the scope, applicability, or configuration of the invention in any way. From the foregoing description, one of ordinary skill in the art will more particularly provide a technical guide to convert at least one exemplary embodiment, wherein various changes may be made, particularly in matters of function and structure of the components described, without departing from the scope of the following claims.

List of reference numerals

1 skeleton

2 elastic sealing body

3 first sealing bevel

4 second sealing bevel

5 is netted bead structure

6 sealing lip

7 spring ring