CN221100680U - Gas environment simulation test device - Google Patents

Abstract

The utility model provides a gas environment simulation test device. The gas environment simulation test device comprises: the experimental simulation device comprises a simulation experiment box body, a sealing door and an air inlet mechanism, wherein the sealing door is hinged and sealed to the simulation experiment box body, the air inlet mechanism is arranged on the simulation experiment box body and comprises two mounting blocks I, a connecting pipe I, an air pump I, an exhaust pipe I, a plurality of L-shaped pipes I and a plurality of valves I, and the two mounting blocks I are fixedly arranged on the outer wall of one side of the simulation experiment box body. The gas environment simulation test device provided by the utility model is simple to operate, and can solve the problems of time and manpower waste caused by complex operation and frequent disassembly and replacement of the connection between the gas source and the pipeline due to the adoption of single one-to-one gas inlet and outlet for simulation experiments.

Description

Gas environment simulation test device

Technical Field

The utility model belongs to the technical field of gas environment simulation tests, and particularly relates to a gas environment simulation test device.

Background

The environment simulation can simulate the indoor environment, is an important tool for detecting products, and is to place detected objects in equipment, and measure and release gas in the equipment.

However, the existing gas environment simulation generally adopts a single one-to-one gas inlet and outlet for simulation experiments, so that the operation is complex, the connection between a gas source and a pipeline is required to be frequently disassembled, assembled and replaced, and time and labor are wasted.

Therefore, it is necessary to provide a new gas environment simulation test apparatus to solve the above-mentioned problems.

Disclosure of utility model

The utility model solves the technical problem of providing the gas environment simulation test device which is simple to operate, can solve the problems of time waste and manpower waste caused by complex operation and frequent disassembly and replacement of the connection between the gas source and the pipeline due to the adoption of a single one-to-one gas inlet and outlet for simulation test.

In order to solve the above technical problems, the gas environment simulation test device provided by the present utility model includes: the simulation experiment box body, sealing door and mechanism of admitting air, sealing door articulated sealed installation is on the simulation experiment box body, mechanism of admitting air sets up on the simulation experiment box body, mechanism of admitting air is including two installation piece I, connecting pipe I, air pump I, exhaust pipe I, a plurality of L type pipe I and a plurality of valve I, two installation piece I equal fixed mounting on one side outer wall of simulation experiment box body, connecting pipe one fixed mounting is on two installation piece I, an air pump fixed mounting is on one side outer wall of simulation experiment box body, an exhaust pipe fixed mounting is on the extraction opening of air pump I, an end that the air pump one was kept away from to the exhaust pipe I communicates with a connecting pipe I, an end that the air pump one was kept away from to the exhaust pipe I extends to in the simulation experiment box body, a plurality of L type pipe I equal fixed mounting is on a connecting pipe I, a plurality of valve I set up respectively on a plurality of L type pipe I.

As a further scheme of the utility model, a disassembly and assembly detection mechanism is arranged in the simulation experiment box body and comprises a mounting plate, a T-shaped block and a gas analyzer, wherein the mounting plate is fixedly arranged in the simulation experiment box body, the T-shaped block is arranged on the top of the mounting plate, the gas analyzer is arranged on the T-shaped block, and an observation window and a control panel are arranged on the outer wall of one side of the sealing door.

As a further scheme of the utility model, the disassembly and assembly detection mechanism further comprises two sliding grooves, two round bars and two moving blocks, wherein the two sliding grooves are formed in the mounting plate, the two round bars are respectively and fixedly arranged in the two sliding grooves, the two moving blocks are respectively and slidably arranged on the two round bars, and the tops of the two moving blocks are fixedly connected with the bottoms of the T-shaped blocks.

As a further scheme of the utility model, two limit slots are formed in the T-shaped block, the disassembly and assembly detection mechanism further comprises two limit components, the two limit components are arranged on the sealing door, each limit component comprises a sliding groove, a sliding rod, a sliding block, a telescopic spring and a limit plug block, the sliding grooves are formed in the mounting plate, the sliding rods are fixedly arranged in the sliding grooves, the sliding blocks are slidably arranged on the sliding rods, the telescopic springs are slidably sleeved on the sliding rods, one ends of the telescopic springs are fixedly connected with the sliding blocks, the other ends of the telescopic springs are fixedly connected with one side inner wall of the sliding grooves, the limit plug blocks are fixedly arranged on the sliding blocks, and the limit plug blocks are matched with the limit slots.

As a further scheme of the utility model, the simulation experiment box body is provided with the exhaust mechanism, the exhaust mechanism comprises two mounting blocks II, a connecting pipe II, a plurality of L-shaped pipes II and a plurality of valves II, the two mounting blocks II are fixedly mounted on the top of the simulation experiment box body, the connecting pipe II is fixedly mounted on the two mounting blocks II, the plurality of L-shaped pipes II are fixedly mounted on the connecting pipe II, and the plurality of valves II are respectively arranged on the plurality of L-shaped pipes II.

As a further scheme of the utility model, the exhaust mechanism further comprises a second air pump, a second exhaust pipe and a second exhaust pipe, wherein the second air pump is fixedly arranged on the top of the simulation experiment box body, the second exhaust pipe is fixedly arranged on the second air pump, one end of the second exhaust pipe extends into the simulation experiment box body, the second exhaust pipe is fixedly arranged on the second air pump, and one end of the second exhaust pipe is communicated with the connecting pipe.

Compared with the related art, the gas environment simulation test device provided by the utility model has the following beneficial effects:

1. According to the utility model, the air inlet mechanism, the dismounting detection mechanism and the exhaust mechanism are arranged in cooperation, so that the operation is simple, and the problems of time and manpower waste caused by complex operation due to the adoption of a single one-to-one air inlet and outlet for simulation experiments and the need of frequent dismounting and replacement of the connection between the air source and the pipeline can be solved.

Drawings

The present utility model is further described below with reference to the accompanying drawings for the convenience of understanding by those skilled in the art.

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a schematic diagram of a mechanism for detecting disassembly and assembly according to the present utility model;

fig. 3 is an enlarged schematic view of the portion a in fig. 2.

In the figure: 1. simulating an experiment box body; 2. sealing the door; 3. a first mounting block; 4. a first connecting pipe; 5. an air pump I; 6. an exhaust pipe I; 7. an exhaust pipe I; 8. an L-shaped pipe I; 9. a valve I; 10. a mounting plate; 11. a T-shaped block; 12. a gas analyzer; 13. a round bar; 14. a moving block; 15. a slide bar; 16. a sliding block; 17. a telescopic spring; 18. a second mounting block; 19. a second connecting pipe; 20. an L-shaped pipe II; 21. an air pump II; 22. an exhaust pipe II; 23. an exhaust pipe II; 24. an observation window; 25. and a control panel.

Detailed Description

Referring to fig. 1, fig. 2 and fig. 3 in combination, fig. 1 is a schematic structural diagram of the present utility model; FIG. 2 is a schematic diagram of a mechanism for detecting disassembly and assembly according to the present utility model; fig. 3 is an enlarged schematic view of the portion a in fig. 2. The gas environment simulation test device comprises: the simulation experiment box body 1, sealing door 2 and mechanism of admitting air, sealing door 2 articulates sealed mounting is on simulation experiment box body 1, mechanism of admitting air sets up on simulation experiment box body 1, mechanism of admitting air is including two installation piece one 3, connecting pipe one 4, air pump one 5, exhaust pipe one 6, exhaust pipe one 7, a plurality of L type pipe one 8 and a plurality of valve one 9, two installation piece one 3 equal fixed mounting on one side outer wall of simulation experiment box body 1, connecting pipe one 4 fixed mounting is on two installation piece one 3, air pump one 5 fixed mounting is on one side outer wall of simulation experiment box body 1, exhaust pipe one 6 fixed mounting is on the extraction opening of air pump one 5, the one end that air pump one 5 was kept away from to exhaust pipe one 6 communicates with connecting pipe one 4, exhaust pipe one 7 fixed mounting is on air pump one 5, the one end that air pump one 5 was kept away from to exhaust pipe one 7 extends to simulation experiment box body 1 in, a plurality of L type pipe one 8 equal fixed mounting is on one 4, a plurality of valve one sets up on a plurality of L type pipe one 8 respectively.

The simulation experiment box 1 is internally provided with a disassembly and assembly detection mechanism, the disassembly and assembly detection mechanism comprises a mounting plate 10, a T-shaped block 11 and a gas analyzer 12, the mounting plate 10 is fixedly arranged in the simulation experiment box 1, the T-shaped block 11 is arranged on the top of the mounting plate 10, the gas analyzer 12 is arranged on the T-shaped block 11, and an observation window 24 and a control panel 25 are arranged on the outer wall of one side of the sealing door 2.

The disassembly and assembly detection mechanism further comprises two sliding grooves, two round bars 13 and two moving blocks 14, wherein the two sliding grooves are formed in the mounting plate 10, the two round bars 13 are fixedly arranged in the two sliding grooves respectively, the two moving blocks 14 are slidably arranged on the two round bars 13 respectively, and the tops of the two moving blocks 14 are fixedly connected with the bottoms of the T-shaped blocks 11.

The T-shaped block 11 is provided with two limiting slots, the disassembly and assembly detection mechanism further comprises two limiting components, the two limiting components are arranged on the sealing door 2, the limiting components comprise a sliding groove, a sliding rod 15, a sliding block 16, a telescopic spring 17 and a limiting plug block, the sliding groove is formed in the mounting plate 10, the sliding rod 15 is fixedly arranged in the sliding groove, the sliding block 16 is slidably arranged on the sliding rod 15, the telescopic spring 17 is slidably sleeved on the sliding rod 15, one end of the telescopic spring 17 is fixedly connected with the sliding block 16, the other end of the telescopic spring 17 is fixedly connected with one side inner wall of the sliding groove, the limiting plug block is fixedly arranged on the sliding block 16, and the limiting plug block is matched with the limiting slot.

By pulling the sliding block 16, the limit plug block can enter or be far away from the limit slot on the T-shaped block 11, so that the T-shaped block 11 can be limited, and the gas analyzer 12 can be conveniently disassembled, replaced and maintained.

The simulation experiment box body 1 is provided with an exhaust mechanism, the exhaust mechanism comprises two mounting blocks II 18, a connecting pipe II 19, a plurality of L-shaped pipes II 20 and a plurality of valves II, the two mounting blocks II 18 are fixedly mounted on the top of the simulation experiment box body 1, the connecting pipe II 19 is fixedly mounted on the two mounting blocks II 18, the plurality of L-shaped pipes II 20 are fixedly mounted on the connecting pipe II 19, and the plurality of valves II are respectively arranged on the plurality of L-shaped pipes II 20.

The exhaust mechanism further comprises a second air pump 21, a second exhaust pipe 22 and a second exhaust pipe 23, wherein the second air pump 21 is fixedly arranged on the top of the simulation experiment box body 1, the second exhaust pipe 22 is fixedly arranged on the second air pump 21, one end of the second exhaust pipe 22 extends into the simulation experiment box body 1, the second exhaust pipe 23 is fixedly arranged on the second air pump 21, and one end of the second exhaust pipe 23 is communicated with the second connecting pipe 19.

The control panel 25 comprises a display and control buttons, a plurality of first L-shaped pipes 8 are connected with other air source pipelines through flanges, and a plurality of second L-shaped pipes 20 are connected with other equipment pipelines for storing air through flanges.

The working principle of the gas environment simulation test device provided by the utility model is as follows:

A first step of: when the gas-liquid mixing simulation experiment device is used, the valve I9 on the corresponding L-shaped pipe I8 is opened, then the gas pump I5 is started to operate, the gas pumping work is carried out under the cooperation of the gas pump I5, the gas exhaust pipe I6 and the corresponding L-shaped pipe I8, then the gas is discharged into the sealing door 2 through the gas exhaust pipe I7, then the corresponding valve I9 is closed, the other valve I9 is opened for gas extraction and discharge work, so that various gases are subjected to mixed simulation experiment in the simulation experiment box 1, and during the simulation experiment, the gases can be detected through the gas analyzer 12 and displayed through the display screen on the control panel 25;

And a second step of: after the simulation experiment is completed, the mixed gas in the simulation experiment box body 1 is extracted through the cooperation of the air pump II 21 and the air exhaust pipe II 22, then the corresponding valve II is opened, and the mixed gas of the simulation experiment is discharged into the gas storage equipment for storage under the cooperation of the air exhaust pipe II 23, the connecting pipe II 19 and the corresponding L-shaped pipe II 20, so that the next simulation experiment is convenient.

It should be noted that, the device structure and the drawings of the present utility model mainly describe the principle of the present utility model, in terms of the technology of the design principle, the arrangement of the power mechanism, the power supply system, the control system, etc. of the device is not completely described, and on the premise that the person skilled in the art understands the principle of the present utility model, the specific details of the power mechanism, the power supply system and the control system can be clearly known, the control mode of the application file is automatically controlled by the controller, and the control circuit of the controller can be realized by simple programming of the person skilled in the art;

The standard parts used in the method can be purchased from the market, and can be customized according to the description of the specification and the drawings, the specific connection modes of the parts are conventional means such as mature bolts, rivets and welding in the prior art, the machines, the parts and the equipment are conventional models in the prior art, and the structures and the principles of the parts are all known by the skilled person through technical manuals or through conventional experimental methods.

Although embodiments of the present utility model have been shown and described, it will be understood by those skilled in the art that various changes, modifications, substitutions and alterations may be made therein without departing from the spirit and scope of the utility model as defined by the appended claims and their equivalents, and in other related technical fields, which are equally encompassed by the scope of the present utility model.

Claims (6)

1. A gas environment simulation test device, comprising:

The simulation experiment box body, sealing door and mechanism of admitting air, sealing door articulated sealed installation is on simulation experiment box body, mechanism of admitting air sets up on simulation experiment box body, mechanism of admitting air is including two installation piece I, connecting pipe I, air pump I, exhaust pipe I, a plurality of L type pipe I and a plurality of valve I, and two installation piece I equal fixed mounting is on the outer wall of one side of simulation experiment box body (1), connecting pipe one fixed mounting is on two installation piece I, an air pump fixed mounting is on the outer wall of one side of simulation experiment box body, an exhaust pipe fixed mounting is on the extraction opening of air pump I, one end that an air pump one was kept away from to exhaust pipe I communicates with connecting pipe I, an end that an air pump one was kept away from to exhaust pipe I extends to in the simulation experiment box body, and a plurality of L type pipe I equal fixed mounting is on one, and a plurality of valve I set up respectively on a plurality of L type pipe I.

2. The gas environment simulation test device according to claim 1, wherein: the device is characterized in that a disassembly and assembly detection mechanism is arranged in the simulation experiment box body and comprises a mounting plate, a T-shaped block and a gas analyzer, wherein the mounting plate is fixedly arranged in the simulation experiment box body, the T-shaped block is arranged on the top of the mounting plate, the gas analyzer is arranged on the T-shaped block, and an observation window and a control panel are arranged on the outer wall of one side of the sealing door.

3. The gas environment simulation test device according to claim 1, wherein: the disassembly and assembly detection mechanism further comprises two sliding grooves, two round bars and two moving blocks, wherein the two sliding grooves are formed in the mounting plate, the two round bars are fixedly arranged in the two sliding grooves respectively, the two moving blocks are slidably arranged on the two round bars respectively, and the tops of the two moving blocks are fixedly connected with the bottoms of the T-shaped blocks.

4. The gas environment simulation test device according to claim 2, wherein: the T-shaped block is provided with two limiting slots, the disassembly and assembly detection mechanism further comprises two limiting components, the two limiting components are arranged on the sealing door, the limiting components comprise a sliding groove, a sliding rod, a sliding block, a telescopic spring and a limiting inserting block, the sliding groove is formed in the mounting plate, the sliding rod is fixedly arranged in the sliding groove, the sliding block is slidably arranged on the sliding rod, the telescopic spring is slidably sleeved on the sliding rod, one end of the telescopic spring is fixedly connected with the sliding block, the other end of the telescopic spring is fixedly connected with one side inner wall of the sliding groove, the limiting inserting block is fixedly arranged on the sliding block, and the limiting inserting block is matched with the limiting slots.

5. The gas environment simulation test device according to claim 1, wherein: the simulation experiment box is provided with an exhaust mechanism, the exhaust mechanism comprises two mounting blocks II, a connecting pipe II, a plurality of L-shaped pipes II and a plurality of valves II, the two mounting blocks II are fixedly mounted on the top of the simulation experiment box, the connecting pipe II is fixedly mounted on the two mounting blocks II, the plurality of L-shaped pipes II are fixedly mounted on the connecting pipe II, and the plurality of valves II are respectively arranged on the plurality of L-shaped pipes II.

6. The gas environment simulation test apparatus according to claim 5, wherein: the exhaust mechanism further comprises a second air pump, a second exhaust pipe and a second exhaust pipe, the second air pump is fixedly arranged on the top of the simulation experiment box body, the second exhaust pipe is fixedly arranged on the second air pump, one end of the second exhaust pipe extends into the simulation experiment box body, the second exhaust pipe is fixedly arranged on the second air pump, and one end of the second exhaust pipe is communicated with the connecting pipe.