CN110823679A

CN110823679A - Follow-up high-temperature inflammable gas sealing device applied to testing machine

Info

Publication number: CN110823679A
Application number: CN201911209227.6A
Authority: CN
Inventors: 陈刚; 冯少武; 林强; 王晓涵
Original assignee: Tianjin University
Current assignee: Tianjin University
Priority date: 2019-11-30
Filing date: 2019-11-30
Publication date: 2020-02-21
Anticipated expiration: 2039-11-30
Also published as: CN110823679B

Abstract

A follow-up high-temperature inflammable gas sealing device applied to a testing machine is characterized in that a flat clamp used for fixing a tested workpiece is arranged on the periphery in an inner cavity, an inner cavity sealing upper cover is arranged on the inner cavity, an outer cavity sealing upper cover is arranged on an outer cavity, the outer periphery of the inner cavity sealing upper cover is fixedly connected with the inner periphery of the outer cavity sealing upper cover through bolts, a ceramic heating sheet is arranged at the outer bottom of the inner cavity, load mechanisms used for applying external force to the tested workpiece are arranged on four side surfaces of the inner cavity, load driving shafts connected with external power are arranged on the four side surfaces of the outer cavity, an inner cavity visual window is arranged on the inner cavity sealing upper cover, a nitrogen gas inlet pipe and an inflammable gas inlet pipe used for introducing nitrogen gas and inflammable gas into the inner cavity and the outer cavity are arranged on the inner cavity and the, and a mixed gas outlet pipe and a mixed gas collecting pipe which are used for guiding the mixed gas in the inner cavity to the outside. The invention is suitable for carrying a mechanical experiment machine in a high-temperature sealing environment.

Description

Follow-up high-temperature inflammable gas sealing device applied to testing machine

Technical Field

The invention relates to a high-temperature inflammable gas sealing device. In particular to a follow-up high-temperature inflammable gas sealing device applied to a testing machine.

Background

In the field of mechanical testing machines, the existing testing machine under normal temperature and normal pressure environment cannot meet the requirements of more and more complex working conditions, many technicians develop mechanical testing systems applied to high-temperature and high-pressure and inflammable gas environments, and the mechanical testing systems provide higher requirements for dynamic sealing technology. The existing sealing method mainly comprises soft and hard packing sealing, labyrinth sealing, piston ring sealing and brush sealing. But the sealing of the follow-up mechanical device can not be realized, and the defects of more limited application conditions, lower working condition adaptability, poorer sealing effect and the like exist. For example, the packing seal is prone to hardening under high temperature conditions, and wear compensation is insufficient; the labyrinth seal belongs to non-contact seal, and the sealing effect is far inferior to that of contact seal; the piston ring seal is the most common high-temperature gas seal structure in the prior art, and the piston ring seal has to work under the conditions of continuous lubrication and cooling and is easy to wear; brush seals are long in production cycle, difficult to manufacture, and require lubrication and cooling. The existing sealing method is not suitable for dynamic sealing of high-temperature inflammable gas due to the defects of low working condition applicability, poor sealing effect and the like.

The sealing device can realize the sealing of inflammable gas in a high-temperature environment, is carried on a mechanical testing machine, and provides an experimental result which is more prone to working conditions for mechanical testing.

Disclosure of Invention

The invention aims to solve the technical problem of providing a follow-up high-temperature inflammable gas sealing device which is loaded on a mechanical testing machine and can seal inflammable gas in a high-temperature environment and is applied to the testing machine.

The technical scheme adopted by the invention is as follows: a follow-up high-temperature inflammable gas sealing device applied to a testing machine comprises an outer cavity and an inner cavity fixed in the middle of the inner cavity, flat plate clamps used for fixing a tested workpiece are symmetrically arranged on the periphery of the inner cavity, an inner cavity sealing upper cover is arranged on the inner cavity, a rectangular annular outer cavity sealing upper cover is arranged on the outer cavity around the inner cavity, the outer periphery of the inner cavity sealing upper cover is fixedly connected with the inner periphery of the outer cavity sealing upper cover through bolts and is hermetically connected with the inner periphery of the outer cavity sealing upper cover through high-temperature resistant sealing columns, a ceramic heating sheet used for heating is arranged at the outer bottom of the inner cavity, load mechanisms used for applying external force to the tested workpiece are arranged on four sides of the inner cavity corresponding to the flat plate clamps, and load driving shafts connected with external power are arranged on the four sides of the outer cavity corresponding to the load mechanisms, the middle part of the sealed upper cover of inner chamber is provided with the interior cavity visual window that is used for observing the inside situation of inner chamber, still be provided with respectively on inner chamber and the outer cavity and run through in proper order the lateral wall of outer cavity and inner chamber is used for the nitrogen gas intake pipe that the inside cavity let in nitrogen gas and is used for the inflammable gas intake pipe that the inside cavity let in inflammable gas, and runs through in proper order the lateral wall of outer cavity and inner chamber is used for leading the mist in the inner chamber to outside mist outlet duct and mist collecting pipe.

The follow-up high-temperature inflammable gas sealing device applied to the testing machine is safe, reliable, flexible in applicable range, capable of providing references for sealing at different temperatures and in gas atmosphere, particularly suitable for carrying high-temperature sealing environment on a mechanical experiment machine, and wide in testing range and high in accuracy.

Drawings

FIG. 1 is a schematic view of the external structure of a follow-up high-temperature flammable gas sealing device applied to a testing machine according to the present invention;

FIG. 2 is an exploded view of the servo-actuated high-temperature flammable gas sealing device applied to the testing machine according to the present invention;

FIG. 3 is a top view of the present invention with the inner chamber seal top and the outer chamber seal top removed;

FIG. 4 is a cross-sectional view A-A of FIG. 1;

FIG. 5 is a schematic view of the construction of the telescoping outer sleeve of the present invention;

fig. 6 is a schematic view of the structure of the spindle in the present invention.

In the drawings

1: an inner cavity 2: outer cavity

3: inner cavity sealing upper cover 4: outer cavity sealing upper cover

5: high-temperature resistant sealing bars 6: inner cavity visual window

7. 8: thermocouple through hole 9: nitrogen inlet pipe

10: mixed gas outlet pipe 11: inflammable gas inlet pipe

12: mixed gas collecting pipe 13: load sensor wire passing hole

14. 16: oxygen concentration verification devices 15, 17: inflammable gas concentration testing device

18: the telescopic jacket 19: ceramic heating plate

20. 21, 22, 23:

load drive shafts

25, 24, 26, 27: flange

28. 29, 30, 31: the load sensor 32: main shaft

33: inner threads 34 of the telescopic sleeve: external thread of telescopic sleeve

35: the corrugated structure 36: main shaft internal thread

37: spindle

external thread

38, 39, 40, 41: flat plate clamp

42: threaded hole 43: through hole

44: internal threaded hole 45: main shaft internal thread

Detailed Description

The following high-temperature flammable gas sealing device applied to a testing machine according to the present invention will be described in detail with reference to the following embodiments and the accompanying drawings.

As shown in fig. 1, 2, 3 and 4, the follow-up high-temperature flammable gas sealing device applied to the testing machine of the invention comprises an outer cavity 2 and an inner cavity 1 fixed in the middle of the inner part of the outer cavity 2, wherein the inner cavity 1 is a key device for realizing sealing, and the outer cavity 2 is a device for inspecting and secondarily protecting the sealing effect, and can be made of stainless steel materials. Interior cavity 1 interior symmetry all around be provided with

flat clamp

38, 39, 40, 41 that are used for fixed workpiece under test, be provided with interior cavity seal upper cover 3 on the interior cavity 1, be provided with the annular outer cavity seal upper cover 4 of rectangle around interior cavity 1 on the outer cavity 2, the outer periphery of interior cavity seal upper cover 3 with through bolt fixed connection between the interior periphery of outer cavity seal upper cover 4, and through 5 looks sealing connection of high temperature resistant sealed column bars, the outer bottom of interior cavity 1 is provided with the ceramic heating piece 19 that is used for the heating, ceramic heating piece 19 inlay in interior cavity 1 bottom surface intermediate layer, realize the inside intensification of interior cavity 1 through thermal radiation's mode.

Load mechanisms for applying external force to the workpiece to be tested are arranged on four side surfaces of the inner cavity 1 corresponding to the

flat plate clamps

38, 39, 40 and 41, the four side surfaces of the outer cavity 2 are provided with

load driving shafts

20, 21, 22 and 23 corresponding to the load mechanisms and connected with external power, the middle part of the inner cavity sealing upper cover 3 is provided with an inner cavity visual window 6 for observing the inner condition of the inner cavity 1, the inner cavity 1 and the outer cavity 2 are respectively provided with a nitrogen inlet pipe 9 which sequentially penetrates through the side walls of the outer cavity 2 and the inner cavity 1 and is used for introducing nitrogen into the inner cavity 1 and a combustible gas inlet pipe 11 for introducing combustible gas into the inner cavity 1, and a mixed gas outlet pipe 10 and a mixed gas collecting pipe 12 which sequentially penetrate through the side walls of the outer cavity 2 and the inner cavity 1 and are used for guiding the mixed gas in the inner cavity 1 to the outside, and are used for measuring gas components.

The nitrogen gas inlet pipe 9, the inflammable gas inlet pipe 11, the mixed gas outlet pipe 10 and the mixed gas collecting pipe 12 are all provided with flame arresters in series, and the flame arresters can have the functions of flame retardance and single-way valves at the same time.

As shown in fig. 1 and 2, four end corners of the upper sealing cover 4 of the outer cavity are respectively and symmetrically provided with 2 oxygen

concentration check devices

14 and 16 for detecting whether nitrogen gas leaks from the inner cavity 1 in the outer cavity 2, and respectively and symmetrically provided with 2 inflammable gas

concentration check devices

15 and 17 for detecting whether inflammable gas leaks from the inner cavity 1 in the outer cavity 2.

As shown in fig. 1 and 2, the middle part of the inner cavity sealing upper cover 3 is formed with a groove which is recessed inwards, the bottom of the groove is communicated with the inside of the inner cavity 1, the inner cavity visual window 6 is embedded into the bottom of the groove, the inner cavity visual window is fixed by bolts, and a sealing structure is formed by bonding high-temperature-resistant glue, so that the sealing performance is ensured.

As shown in fig. 2, thermocouple through holes 7 and 8 are also symmetrically formed on the inner cavity 1 and the outer cavity 2, respectively, for making thermocouples sequentially penetrate through the side walls of the outer cavity 2 and the inner cavity 1 to detect the temperature in the inner cavity 1.

As shown in fig. 2 and 4, the load mechanism includes: the four sides of the inner cavity 1 are symmetrically provided with a through threaded hole 42, the four sides of the outer cavity 2 are provided with a through hole 43 corresponding to the threaded hole 42, a

load sensor

28, 29, 30, 31 is arranged between the four outer side walls of the inner cavity 1 and the four inner side walls of the outer cavity 2, the

load sensor

28, 29, 30, 31 is provided with a through inner threaded hole 44 formed by the threaded hole 42 and the through hole 43, a telescopic outer sleeve 18 and a main shaft 32 are further arranged, the main shaft 32 penetrates through the telescopic outer sleeve 18, one end of the threaded hole 42 of the inner cavity 1 is connected with a

flat clamp

38, 39, 40, 41 positioned in the inner cavity 1, the other end of the threaded hole is connected with the threaded hole 42 of the

load sensor

28, 29, 30, 31, the telescopic outer sleeve 18 is positioned in the threaded hole 42 of the inner cavity 1, one side of the inner cavity 1 is in threaded connection with the threaded hole 42 of the inner cavity 1, the other end is screwed to the main shaft 32, and the

load sensors

28, 29, 30, and 31 are positioned on the outer chamber 2 side and are connected to

load driving shafts

20, 21, 22, and 23 inserted through holes 43 in the outer chamber 2 by female screw holes 44.

As shown in fig. 1 and 2, the side wall of the outer cavity 2 is provided with a load sensor wire through hole 13 for connecting the

load sensors

28, 29, 30, and 31 with external equipment, and the load sensor wire through hole 13 and a through conduit pipe realize static sealing through a sealing ring.

As shown in fig. 5, the telescopic outer sleeve 18 is a tube structure, one end of the tube structure is formed with a telescopic inner thread 33 for connecting with the outer thread on the main shaft 32, the other end is formed with a telescopic outer thread 34 for connecting with the threaded hole 42 on the inner cavity 1, and a telescopic corrugated structure 35 is formed in the middle of the tube structure, so that the tube structure can be stretched under the action of the

load driving shafts

20, 21, 22 and 23, and the follow-up sealing is realized through the telescopic structure.

As shown in fig. 6, a main shaft internal thread 36 for connecting the

flat clamps

38, 39, 40, 41 is formed at one end of the main shaft 32, a main shaft external thread 37 for connecting the

load sensors

28, 29, 30, 31 is formed at the other end, and a main shaft internal thread 45 for screwing with the telescopic sleeve internal thread 33 on the telescopic sleeve 18 is formed on the shaft body of the main shaft 32 adjacent to the main shaft external thread 37.

The invention relates to a follow-up high-temperature inflammable gas sealing device applied to a testing machine, wherein nitrogen is respectively introduced into an inner cavity 1 through a nitrogen inlet pipe 9 and an inflammable gas inlet pipe 11 until oxygen values measured by oxygen

concentration inspection devices

14 and 16 are zero. Hydrogen which forms inflammable gas is introduced into the inner cavity 1 through the air inlet pipe until the concentration of the hydrogen reaches a set value. And electrifying the ceramic heating sheet 19 until the temperature value in the inner cavity 1 measured by the thermocouple is +/-3 ℃ of the set temperature, and then carrying out preset experimental operation.

Once the gas concentration detection device detects that the outer cavity 2 has leaked abnormal gas, the heating power supply is immediately cut off, and a large amount of nitrogen is introduced into the inner cavity 1 to ensure safety.

Claims

1. The follow-up high-temperature inflammable gas sealing device applied to the testing machine comprises an outer cavity (2) and an inner cavity (1) fixed in the middle in the outer cavity (2), wherein flat plate clamps (38, 39, 40 and 41) used for fixing a tested workpiece are symmetrically arranged on the periphery in the inner cavity (1), the follow-up high-temperature inflammable gas sealing device is characterized in that an inner cavity sealing upper cover (3) is arranged on the inner cavity (1), a rectangular annular outer cavity sealing upper cover (4) is arranged on the outer cavity (2) around the inner cavity (1), the outer periphery of the inner cavity sealing upper cover (3) is fixedly connected with the inner periphery of the outer cavity sealing upper cover (4) through bolts and is hermetically connected with a high-temperature resistant sealing column bar (5), a ceramic heating sheet (19) used for heating is arranged at the outer bottom of the inner cavity (1), and the flat plate clamps (38, 40 and the flat plate clamps (41) are arranged on four side surfaces of the inner cavity (1), 39. 40, 41) are correspondingly provided with load mechanisms for applying external force to the workpiece to be tested, load driving shafts (20, 21, 22, 23) connected with external power are arranged on four side surfaces of the outer cavity (2) corresponding to the load mechanisms, an inner cavity visual window (6) for observing the inner condition of the inner cavity (1) is arranged in the middle of the inner cavity sealing upper cover (3), the inner cavity (1) and the outer cavity (2) are respectively provided with a nitrogen inlet pipe (9) which sequentially penetrates through the side walls of the outer cavity (2) and the inner cavity (1) and is used for introducing nitrogen into the inner cavity (1) and a combustible gas inlet pipe (11) which is used for introducing combustible gas into the inner cavity (1), and a mixed gas outlet pipe (10) and a mixed gas collecting pipe (12) which sequentially penetrate through the side walls of the outer cavity (2) and the inner cavity (1) and are used for guiding the mixed gas in the inner cavity (1) to the outside.

2. The follow-up high-temperature inflammable gas sealing device applied to the testing machine according to claim 1, characterized in that four corners of the outer cavity sealing upper cover (4) are respectively and symmetrically provided with 2 oxygen concentration checking devices (14, 16) for detecting whether nitrogen gas leaks from the inner cavity (1) or not in the outer cavity (2), and 2 inflammable gas concentration checking devices (15, 17) for detecting whether inflammable gas leaks from the inner cavity (1) or not in the outer cavity (2) or not.

3. The follow-up high-temperature inflammable gas sealing device applied to the testing machine according to claim 1, wherein a concave groove is formed in the middle of the inner cavity sealing upper cover (3), the bottom of the groove and the inside of the inner cavity (1) are of a communicating structure, and the inner cavity visual window (6) is embedded in the bottom of the groove and is bonded by high-temperature resistant glue to form a sealing structure.

4. The follow-up high-temperature inflammable gas sealing device applied to the testing machine according to claim 1, wherein fire arresters are arranged on the nitrogen gas inlet pipe (9), the inflammable gas inlet pipe (11), the mixed gas outlet pipe (10) and the mixed gas collecting pipe (12) in series.

5. The follow-up high-temperature inflammable gas sealing device applied to the testing machine according to claim 1, characterized in that thermocouple through holes (7, 8) are symmetrically formed on the inner cavity (1) and the outer cavity (2) respectively, and are used for enabling thermocouples to sequentially penetrate through the side walls of the outer cavity (2) and the inner cavity (1) to detect the temperature in the inner cavity (1).

6. The follow-up high-temperature flammable gas sealing device applied to the testing machine according to claim 1, wherein the loading mechanism comprises: the inner cavity is characterized in that four side surfaces of the inner cavity (1) are symmetrically provided with a through threaded hole (42), four side surfaces of the outer cavity (2) are provided with a through hole (43) corresponding to the threaded hole (42), a load sensor (28, 29, 30, 31) is arranged between four outer side walls of the inner cavity (1) and four inner side walls of the outer cavity (2), the load sensor (28, 29, 30, 31) is provided with a through inner threaded hole (44) corresponding to the threaded hole (42) and the through hole (43), a telescopic outer sleeve (18) and a main shaft (32) are further arranged, the main shaft (32) penetrates through the telescopic outer sleeve (18) and one end of the main shaft penetrates through the threaded hole (42) of the inner cavity (1) to be connected with flat plate clamps (38, 39, 40, 41) positioned in the inner cavity (1), the other end threaded connection on the screw hole (42) of load cell (28, 29, 30, 31), flexible overcoat (18) are located one side threaded connection of interior cavity (1) is in the screw hole (42) of interior cavity (1), other end threaded connection be in on main shaft (32), load cell (28, 29, 30, 31) are located outer cavity (2) one side and pass through internal thread hole (44) connection load drive axle (20, 21, 22, 23) of perforating hole (43) on outer cavity (2).

7. The follow-up high-temperature inflammable gas sealing device applied to the testing machine according to claim 6, wherein the telescopic jacket (18) is a tube structure, one end of the tube structure is formed with a telescopic jacket internal thread (33) for connecting with the external thread on the main shaft (32), the other end of the tube structure is formed with a telescopic jacket external thread (34) for connecting with the threaded hole (42) on the inner cavity (1), and the middle part of the tube structure is formed with a telescopic corrugated structure (35).

8. The follow-up high-temperature combustible gas sealing device applied to the testing machine is characterized in that one end of the main shaft (32) is provided with a main shaft internal thread (36) for connecting the flat clamps (38, 39, 40, 41), the port at the other end is provided with a main shaft external thread (37) for connecting the load sensors (28, 29, 30, 31), and a main shaft internal thread (45) for being in threaded connection with a telescopic sleeve internal thread (33) on the telescopic sleeve (18) is formed on the shaft body of the main shaft (32) and close to the main shaft external thread (37).

9. The follow-up high-temperature inflammable gas sealing device applied to the testing machine according to claim 1, wherein the side wall of the outer cavity (2) is provided with a load sensor wire through hole (13) for connecting the load sensor (28, 29, 30, 31) with external equipment, and the load sensor wire through hole (13) and a through conduit are statically sealed through a sealing ring.