CN116817053A - Rotary joint adopting Tesla valve and sealing method thereof - Google Patents

Abstract

The invention discloses a rotary joint adopting a Tesla valve, which comprises a dynamic rotary member and a static rotary member which are in conical cylinder shapes, wherein the dynamic rotary member and the static rotary member are in nested rotary connection with each other, an elastic compression structure for realizing elastic compression along an axial direction is arranged between the dynamic rotary member and the static rotary member, a Tesla valve runner which is spiral is arranged on the outer side of the static rotary member, a third support plate is arranged on the outer side of the wide end of the dynamic rotary member, a second support plate is arranged on the outer side of the wide end of the static rotary member, a labyrinth sealing structure is arranged between the second support plate and the third support plate, when air outside flows towards the inner part of the static rotary member through a first Tesla valve runner, gas flows reversely in the first Tesla valve runner, the energy loss of the gas flowing in the first Tesla valve runner is increased, and the sealing effect on the wide-mouth end of the dynamic rotary member is achieved.

Description

Rotary joint adopting Tesla valve and sealing method thereof

Technical Field

The invention relates to the technical field of rotary sealing, in particular to a rotary joint adopting a Tesla valve and a sealing method thereof.

Background

At present, the hard connection structure between the rotary joint and the rotary cylinder is commonly used as a pipeline connecting device, the connected pipeline can relatively rotate and can be used for conveying various media such as gas, liquid, oil and the like, and the existing mechanical sealing mode such as packing sealing, labyrinth sealing and the like has poor sealing effect at the joint of the rotary cylinder, so that the condition of gas leakage or liquid leakage is often caused.

The application number is CN201310433260.3, and the proximal end shell is connected with the outlet end shell through bolts; the proximal movable sealing ring is arranged in the proximal housing and forms a seal with the shaft sleeve; one end of the proximal movable sealing ring is provided with a proximal bearing pad, and the other end of the proximal movable sealing ring is provided with a proximal static sealing ring;

among the above-mentioned prior art, sealing means is single and the effect is not good, can't effectually play sealed effect to junction.

Disclosure of Invention

The present invention aims to solve the above problems by providing a rotary joint using a tesla valve, which is intended to overcome the drawbacks of the prior art, as described in detail below.

In order to achieve the above purpose, the present invention provides the following technical solutions:

the invention provides a rotary joint adopting a Tesla valve, which comprises a dynamic rotary member and a static rotary member which are in conical cylinder shapes, wherein the dynamic rotary member and the static rotary member are in nested rotary connection with each other, an elastic compression structure for realizing elastic compression along an axial direction is arranged between the dynamic rotary member and the static rotary member, a Tesla valve runner which is spiral is arranged on the outer side of the static rotary member, a third support plate is arranged on the outer side of the wide end of the dynamic rotary member, a second support plate is arranged on the outer side of the wide end of the static rotary member, and a labyrinth sealing structure is arranged between the second support plate and the third support plate.

Preferably, a first packing seal ring is arranged between the narrow end face of the static rotary member and the inner side end face of the first support plate, and a second packing seal ring is arranged between the third support plate and the second support plate.

Preferably, the elastic pressing structure comprises more than four guide rods which are uniformly distributed at equal angles by taking the central axis of the dynamic rotating member as a center, the axial directions of the guide rods are parallel to each other, one end of each guide rod is fixedly connected to the second supporting plate, the outer side of the first supporting plate is rotationally connected with an outer sleeve ring through a first bearing, the other ends of the guide rods slide through the outer sleeve ring and are fixedly connected with a compression ring through bolts, and springs are nested on the outer sides of the guide rods between the outer sleeve ring and the compression ring.

Preferably, a support ring is fixedly arranged on one side, close to the third support plate, of the second support plate, and a second bearing is arranged between the inner side of the support ring and the outer side of the third support plate.

Preferably, the labyrinth seal structure comprises a first sealing ring and a second sealing ring, wherein a first annular caulking groove and a second annular caulking groove are respectively formed in one sides, close to each other, of the second supporting plate and the third supporting plate, one side of the first sealing ring is embedded into the first annular caulking groove and is connected with one end of a connecting bolt, and the other end of the connecting bolt penetrates out of the third supporting plate and is in threaded connection with a nut.

Preferably, a plurality of second baffle rings which are uniformly distributed are fixedly connected to one side, close to the first sealing ring, of the second sealing ring, second baffle grooves which are in clearance fit connection with the second baffle rings are formed in the first sealing ring, the second baffle rings are arranged in concentric circles, a plurality of first baffle rings which are uniformly distributed are fixedly connected to one side, close to the second sealing ring, of the first sealing ring, the first baffle rings are arranged in concentric circles, and first baffle grooves which are in clearance fit connection with the first baffle rings are formed in the second sealing ring;

when the first sealing ring and the second sealing ring are matched and connected with each other, the first baffle grooves and the second baffle grooves are staggered at intervals in a herringbone mode.

Preferably, the narrow end of the dynamic rotating member is fixedly connected with a first conduit, and the wide end of the static rotating member is fixedly connected with a second conduit.

A method of sealing a rotary joint employing a tesla valve, comprising the steps of:

s1: the narrow end of the static rotating member is inserted into the dynamic rotating member from the wide end opening of the dynamic rotating member, at the moment, the first sealing ring is embedded into the first annular caulking groove, the second sealing ring is embedded into the second annular caulking groove, the first sealing ring and the second sealing ring are respectively and fixedly arranged through connecting bolts and nuts, the second baffle ring is driven to rotate in the second baffle groove when the dynamic rotating member rotates, and the first baffle ring rotates in the first baffle groove, so that labyrinth sealing before the dynamic rotating member and the static rotating member is realized;

s2: the narrow ends of the static rotary member are sealed with the first support plate through a first packing seal ring, the third support plate is sealed with the second support plate through a second packing seal ring, and the first packing seal ring and the second packing seal ring are matched to realize packing sealing on two ports of the static rotary member;

s3: due to the pressure difference between the outside and the inside of the static rotating member, when the outside air flows towards the inside of the static rotating member through the first Tesla valve flow passage, the air flows reversely in the first Tesla valve flow passage, so that the energy loss of the air flowing in the first Tesla valve flow passage is increased, and the sealing effect on the wide opening end of the dynamic rotating member is achieved.

The beneficial effects are that:

1. the sealing at the port of the second filler sealing ring is realized by adopting a filler sealing mode through the first filler sealing ring and the second filler sealing ring, the first sealing ring and the second sealing ring are matched with each other to realize labyrinth sealing of a high-pressure material port and a wide port end of a dynamic rotating member, and the Tesla valve runner can realize sealing between conical contact surfaces of the dynamic rotating member and a static rotating member;

2. the first baffle ring and the second baffle ring can be matched to block air flow and reversely flow, block air flow and consume energy, and the whole sealing effect is greatly improved by matching with a Tesla valve runner and packing sealing;

3. the elastic compression structure has the function of axially pushing the dynamic rotating member and the static rotating member, so that the dynamic rotating member and the static rotating member are elastically compressed and close along the axial direction, and the sealing effect of the first packing sealing ring and the second packing sealing ring is better;

4. when the outside air flows towards the inside of the static rotating component through the first Tesla valve flow channel, the air flows reversely in the first Tesla valve flow channel, so that the energy loss of the air flowing in the first Tesla valve flow channel is increased, and the sealing effect on the wide-mouth end of the dynamic rotating component is achieved.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the invention, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

FIG. 1 is a front view of the present invention;

FIG. 2 is a perspective view of FIG. 1 of the present invention;

FIG. 3 is a front view of a static rotary member of the present invention;

fig. 4 is an enlarged view of a portion of fig. 1 a of the present invention.

The reference numerals are explained as follows: 1. a dynamic rotation member; 2. a static rotating member; 3. a first support plate; 4. a first conduit; 5. a second conduit; 6. a first packing seal ring; 7. a first bearing; 8. an elastic compression structure; 8a, a guide rod; 8b, an outer collar; 8c, a spring; 8d, a compression ring; 9. a second support plate; 10. a tesla valve flow passage; 11. a first seal ring; 12. a second seal ring; 13. a first baffle ring; 14. a first barrier groove; 15. a connecting bolt; 16. a nut; 17. a second baffle ring; 18. a second baffle slot; 19. a third support plate; 20. a support ring; 21. a second bearing; 22. and a second packing seal ring.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the technical solutions of the present invention will be described in detail below. It will be apparent that the described embodiments are only some, but not all, embodiments of the invention. All other embodiments, based on the examples herein, which are within the scope of the invention as defined by the claims, will be within the scope of the invention as defined by the claims.

Referring to fig. 1-4, the invention provides a rotary joint adopting a tesla valve, which comprises a dynamic rotary member 1 and a static rotary member 2, wherein the dynamic rotary member 1 and the static rotary member 2 are in conical cylinder shapes, the dynamic rotary member 1 and the static rotary member 2 are in nested rotary connection with each other, the dynamic rotary member 1 and the static rotary member 2 are coaxial with each other, an elastic compression structure 8 for realizing elastic compression along the axial direction is arranged between the dynamic rotary member 1 and the static rotary member 2, a tesla valve runner 10 in a spiral shape is arranged on the outer side of the static rotary member 2, a third support plate 19 is arranged on the outer side of the wide end of the dynamic rotary member 1, a second support plate 9 is arranged on the outer side of the wide end of the static rotary member 2, and a labyrinth sealing structure is arranged between the second support plate 9 and the third support plate 19.

A first packing seal 6 is arranged between the narrow end face of the static rotary member 2 and the inner side end face of the first support plate 3, and a second packing seal 22 is arranged between the third support plate 19 and the second support plate 9.

As shown in fig. 1 and 2 of the specification, the elastic compression structure 8 includes four or more guide rods 8a uniformly distributed at equal angles with respect to the central axis of the dynamic rotation member 1, the axial directions of the guide rods 8a are parallel to each other, one end of each guide rod 8a is fixedly connected to the second support plate 9, the outer side of the first support plate 3 is rotatably connected with an outer sleeve ring 8b through a first bearing 7, the other ends of the guide rods 8a slide through the outer sleeve ring 8b and are fixedly connected with a compression ring 8d through bolts, and a spring 8c is nested outside the guide rod 8a between the outer sleeve ring 8b and the compression ring 8 d. In practical application, the elastic compression structure 8 has the function of pushing the dynamic rotating member 1 and the static rotating member 2 to be axially close to each other, so that the dynamic rotating member 1 and the static rotating member 2 are elastically compressed and close to each other along the axial direction, and the sealing effect of the first packing seal ring 6 and the second packing seal ring 22 can be better.

A support ring 20 is fixedly arranged on the side of the second support plate 9 close to the third support plate 19, and a second bearing 21 is arranged between the inner side of the support ring 20 and the outer side of the third support plate 19.

Referring to fig. 1 and 4 of the specification, the labyrinth seal structure includes a first seal ring 11 and a second seal ring 12, a first annular caulking groove and a second annular caulking groove are respectively formed on one side of the second support plate 9 and one side of the third support plate 19, which are close to each other, one side of the first seal ring 11 is embedded into the first annular caulking groove and is connected with one end of a connecting bolt 15, and the other end of the connecting bolt 15 penetrates out of the third support plate 19 and is in threaded connection with a nut 16. A plurality of second baffle rings 17 which are uniformly distributed are fixedly connected to one side, close to the first sealing ring 11, of the second sealing ring 12, second baffle grooves 18 which are in clearance fit connection with the second baffle rings 17 are formed in the first sealing ring 11, the second baffle rings 17 are arranged in concentric circles, a plurality of first baffle rings 13 which are uniformly distributed are fixedly connected to one side, close to the second sealing ring 12, of the first sealing ring 11, the first baffle rings 13 are arranged in concentric circles, and first baffle grooves 14 which are in clearance fit connection with the first baffle rings 13 are formed in the second sealing ring 12; when the first sealing ring 11 and the second sealing ring 12 are matched and connected with each other, the first baffle groove 14 and the second baffle groove 18 are staggered at intervals in a herringbone shape. Through the above-mentioned specific structural design, when external air gets into static rotating member 2 through the wide mouth end of dynamic rotating member 1 under the atmospheric pressure difference effect, first baffle ring 13 and second baffle ring 17 can cooperate to realize blocking and reverse flow to the air current, realize blocking and energy consumption to the gas flow, cooperate tesla valve runner 10 and packing seal, improve holistic sealed effect greatly.

The narrow end of the dynamic rotating member 1 is fixedly connected with a first conduit 4, and the wide end of the static rotating member 2 is fixedly connected with a second conduit 5.

The sealing method comprises the following steps:

the narrow end of the static rotating member 2 is inserted into the dynamic rotating member 1 from the wide end of the dynamic rotating member 1, at the moment, the first sealing ring 11 is embedded into the first annular caulking groove, the second sealing ring 12 is embedded into the second annular caulking groove, the first sealing ring 11 and the second sealing ring 12 are respectively fixed tightly through the connecting bolt 15 and the nut 16, the second baffle ring 17 is driven to rotate in the second baffle groove 18 when the dynamic rotating member 1 rotates, and the first baffle ring 13 rotates in the first baffle groove 14, so that labyrinth sealing before the dynamic rotating member 1 and the static rotating member 2 is realized;

the narrow ends of the static rotary member 2 are sealed with the first support plate 3 through the first packing seal ring 6, the third support plate 19 is sealed with the second support plate 9 through the second packing seal ring 22, and the packing seals of the two ports of the static rotary member 2 are realized through the cooperation of the first packing seal ring 6 and the second packing seal ring 22;

due to the pressure difference between the outside and the inside of the static rotary member 2, when the outside air flows towards the inside of the static rotary member 2 through the first tesla valve flow passage 6, the air flows reversely in the first tesla valve flow passage 6, so that the energy loss of the air flowing in the first tesla valve flow passage 6 is increased, and the sealing effect on the wide opening end of the dynamic rotary member 1 is achieved.

In practical application, the first packing seal ring 6 and the second packing seal ring 22 adopt a packing seal mode to realize the sealing at the port of the second packing seal ring 22, the first seal ring 11 and the second seal ring 12 can realize the labyrinth sealing of the high-pressure material port and the wide-mouth end of the dynamic rotating component 1 in a matching way, and the Tesla valve runner 10 can realize the sealing between the conical contact surfaces of the dynamic rotating component 1 and the static rotating component 2.

The foregoing is merely illustrative of the present invention, and the present invention is not limited thereto, and any person skilled in the art will readily recognize that variations or substitutions are within the scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (8)

1. A rotary joint employing tesla valve, characterized in that: including dynamic rotating member (1) and static rotating member (2) that the appearance all is conical cylinder shape, dynamic rotating member (1) and static rotating member (2) are nested rotation each other and are connected, are provided with between dynamic rotating member (1) and the static rotating member (2) and are used for realizing along the elasticity compact structure (8) of axial elasticity compact, tesla valve runner (10) that are heliciform have been seted up in the outside of static rotating member (2), the wide end outside of dynamic rotating member (1) is provided with third backup pad (19), the wide end outside of static rotating member (2) is provided with second backup pad (9), is provided with labyrinth seal structure between second backup pad (9) and the third backup pad (19).

2. A rotary union employing a tesla valve as claimed in claim 1 wherein: a first packing sealing ring (6) is arranged between the narrow end face of the static rotary member (2) and the inner side end face of the first supporting plate (3), and a second packing sealing ring (22) is arranged between the third supporting plate (19) and the second supporting plate (9).

3. A rotary union employing a tesla valve as claimed in claim 1 wherein: the elastic compression structure (8) comprises more than four guide rods (8 a) which are uniformly distributed by taking the central axis of the dynamic rotation component (1) as the center and have equal angles, the axial directions of the guide rods (8 a) are parallel to each other, one end of each guide rod (8 a) is fixedly connected to a second support plate (9), the outer side of the first support plate (3) is rotatably connected with an outer sleeve ring (8 b) through a first bearing (7), the other end of each guide rod (8 a) slides through the outer sleeve ring (8 b) and is fixedly connected with a compression ring (8 d) through a bolt, and a spring (8 c) is nested outside the guide rod (8 a) between the outer sleeve ring (8 b) and the compression ring (8 d).

4. A rotary union employing a tesla valve as claimed in claim 1 wherein: a support ring (20) is fixedly arranged on one side, close to the third support plate (19), of the second support plate (9), and a second bearing (21) is arranged between the inner side of the support ring (20) and the outer side of the third support plate (19).

5. A rotary union employing a tesla valve as claimed in claim 1 wherein: the labyrinth seal structure comprises a first sealing ring (11) and a second sealing ring (12), wherein a first annular caulking groove and a second annular caulking groove are respectively formed in one side, close to each other, of the second supporting plate (9) and the third supporting plate (19), one side of the first sealing ring (11) is embedded into the first annular caulking groove and is connected with one end of a connecting bolt (15), and the other end of the connecting bolt (15) penetrates out of the third supporting plate (19) and is connected with a nut (16) in a threaded manner.

6. A rotary union employing a tesla valve as claimed in claim 5 wherein: a plurality of second baffle rings (17) which are uniformly distributed are fixedly connected to one side, close to the first sealing ring (11), of the second sealing ring (12), second baffle grooves (18) which are in clearance fit connection with the second baffle rings (17) are formed in the first sealing ring (11), the second baffle rings (17) are arranged in concentric circles, a plurality of first baffle rings (13) which are uniformly distributed are fixedly connected to one side, close to the second sealing ring (12), of the first sealing ring (11), the first baffle rings (13) are arranged in concentric circles, and first baffle grooves (14) which are in clearance fit connection with the first baffle rings (13) are formed in the second sealing ring (12);

when the first sealing ring (11) and the second sealing ring (12) are connected in a matched mode, the first baffle grooves (14) and the second baffle grooves (18) are staggered at intervals in a herringbone mode.

7. A rotary union employing a tesla valve as claimed in claim 1 wherein: the narrow end of the dynamic rotating component (1) is fixedly connected with a first conduit (4), and the wide end of the static rotating component (2) is fixedly connected with a second conduit (5).

8. A method of sealing a rotary union employing a tesla valve according to claim 1, characterized by: the method comprises the following steps:

s1: the narrow end of the static rotating member (2) is inserted into the dynamic rotating member (1) from the wide end of the dynamic rotating member (1), at the moment, the first sealing ring (11) is embedded into the first annular embedding groove, the second sealing ring (12) is embedded into the second annular embedding groove, the first sealing ring (11) and the second sealing ring (12) are respectively fixed and fastened through the connecting bolt (15) and the nut (16), the second baffle ring (17) is driven to rotate in the second baffle groove (18) when the dynamic rotating member (1) rotates, and the first baffle ring (13) rotates in the first baffle groove (14), so that labyrinth sealing before the dynamic rotating member (1) and the static rotating member (2) is realized;

s2: the narrow ends of the static rotary component (2) are sealed with each other through a first filler sealing ring (6) and a first supporting plate (3), a third supporting plate (19) and a second supporting plate (9) are sealed through a second filler sealing ring (22), and the first filler sealing ring (6) and the second filler sealing ring (22) are matched to realize filler sealing of two ports of the static rotary component (2);

s3: due to the pressure difference between the outside and the inside of the static rotating component (2), when the outside air flows towards the inside of the static rotating component (2) through the first Tesla valve flow passage (6), the air flows reversely in the first Tesla valve flow passage (6), so that the energy loss of the air flowing in the first Tesla valve flow passage (6) is increased, and the sealing effect on the wide opening end of the dynamic rotating component (1) is achieved.