CN219654370U - Large-scale stainless steel airtight test cabin of modularization installation - Google Patents

Abstract

The utility model provides a modularized installation large-scale stainless steel closed test cabin which comprises a top plate module, a bottom plate module, an inner wallboard module and an external hanging plate which are in modularized design by a factory, wherein a hexahedral frame is formed by splicing a plurality of inner wallboard modules, the top plate module is paved above the hexahedral frame formed by splicing the inner wallboard modules in parallel, the bottom plate module is installed below the hexahedral frame formed by splicing the inner wallboard modules in parallel, the external hanging plate is installed on the left side surface, the right side surface, the rear side surface and the front side surface of the hexahedral frame formed by splicing the inner wallboard modules, and an emergency stop switch, a closed cabin control screen, a sampling valve, a power socket, a glove, an observation window and a closed door are correspondingly installed on the external hanging plate. According to the utility model, the stainless steel plate and the square tube are in modularized design, so that rapid installation is realized in a factory modularized production and installation site, and the environment-friendly sealant is matched to form the closed cabin with high sealing performance, thereby improving the installation efficiency and reducing the installation cost.

Description

Large-scale stainless steel airtight test cabin of modularization installation

Technical Field

The utility model relates to a closed test cabin, in particular to a modularized installation large-sized stainless steel closed test cabin.

Background

Test cabins (also known as climate cabins, environmental cabins) are widely used in the field of detection in relation to the quality of indoor air. Along with the continuous improvement of the quality requirements of people on air purification products, the requirements of more and more third-party detection institutions and manufacturers of purification products on product detection performance equipment are also continuously improved, and the requirements of a large-scale air purification performance test cabin are also rapidly increased; at present, a relatively large-sized airtight environment test cabin is mostly constructed and installed on site by adopting stainless steel or glass materials and a stainless steel frame, and the problems that the construction link is complex, potential safety hazards are easily caused by on-site welding and the construction time is long often exist.

Disclosure of Invention

Aiming at the defects of the prior art, the utility model provides a modularized installation large-sized stainless steel closed test cabin, which is produced in a modularized manner in a factory by connecting a stainless steel plate with a square tube in a modularized design, and is provided with an environment-friendly sealant to form a high-tightness stainless steel closed cabin body, so that the installation efficiency is improved, and the installation cost is reduced.

In order to achieve the technical scheme, the utility model provides a modularized installation large-sized stainless steel closed test cabin, which comprises the following components: the intelligent monitoring system comprises a plurality of top plate modules, a plurality of bottom plate modules, a plurality of inner wall plate modules and a plurality of cladding plates, wherein the plurality of top plate modules, the plurality of bottom plate modules, the plurality of inner wall plate modules and the plurality of cladding plates are arranged in a modular manner, the plurality of top plate modules are spliced between the plurality of inner wall plate modules to form a hexahedral frame, the plurality of top plate modules are parallelly arranged below the hexahedral frame formed by splicing the inner wall plate modules, the cladding plates are arranged on the left side surface, the right side surface, the rear side surface and the front side surface of the hexahedral frame formed by splicing the inner wall plate modules, and the cladding plates arranged on the front side surface of the hexahedral frame are correspondingly provided with an emergency stop switch, a closed cabin control screen, a sampling valve, a power socket, gloves, an observation window and a closed door.

Preferably, the inner wallboard module is formed by welding a stainless steel plate, a square tube and a reinforcing rib, the joint of the inner side of the square tube and the stainless steel plate is coated with environment-friendly sealant, and the adjacent inner wallboard modules are connected through bolts and lamb fastening arranged on the square tube.

Preferably, the bottom plate module is formed by welding a stainless steel square tube and a stainless steel plate, glass cement is coated at the joint of the inner side of the square tube and the stainless steel plate, the adjacent bottom plate modules are connected through bolts and lamb fastening arranged on the stainless steel square tube, and the stainless steel square tube on the bottom plate module is connected with the square tube arranged at the bottom of the inner wall plate module through bolts and lamb fastening.

Preferably, the roof module is formed by welding a stainless steel plate, a square tube and a reinforcing rib, glass cement is coated at the joint of the inner side of the square tube and the stainless steel plate, the adjacent roof modules are connected through bolts and lambda fastening arranged on the square tube respectively, and the square tube on the roof module is connected with the square tube arranged on the top of the inner wallboard module through bolts and lambda fastening.

Preferably, the cladding plate is formed by welding stainless steel square tubes and stainless steel plates, adjacent cladding plates are connected through bolts and lamb fastening arranged on the stainless steel square tubes, the stainless steel square tubes at the top of the cladding plate are connected with the square tubes arranged at the top of the inner wall plate module through bolts and lamb fastening, and the stainless steel square tubes at the bottom of the cladding plate are connected with the square tubes arranged at the bottom of the inner wall plate module through bolts and lamb fastening.

Preferably, the observation window comprises an inner observation window frame, rubber U-shaped strips, toughened glass, an outer observation window frame and an observation window glass supporting frame, wherein the observation window glass supporting frame is welded in the cladding, the toughened glass is mounted on the observation window glass supporting frame in a fit mode through the rubber U-shaped strips, the inner observation window frame is fixed on the inner side of the observation window glass supporting frame through bolts, and the outer observation window frame is fixed on the outer side of the observation window glass supporting frame through bolts.

The modularized installation large-sized stainless steel closed test cabin has the beneficial effects that: the modularized installation large-scale stainless steel airtight test cabin is simple in structure and reasonable in design, the stainless steel plate and the square tube are modularized to be designed into the top plate module, the bottom plate module, the inner wall plate module and the outer wall plate, the factory modularized production is realized, and during actual installation, the inner wall plate module, the top plate module, the bottom plate module and the outer wall plate are only required to be assembled quickly according to design requirements, and the environment-friendly sealant is matched, so that the high-tightness stainless steel airtight cabin body is formed, the installation efficiency is improved, and the installation cost is reduced.

Drawings

FIG. 1 is a schematic perspective view of the present utility model;

FIG. 2 is an exploded perspective view of the present utility model;

FIG. 3 is a cross-sectional view of the door frame at A in FIG. 2 connected to the floor module;

FIG. 4 is a cross-sectional view of the wallboard module and the bottom plate, top plate module of FIG. 2B;

FIG. 5 is a schematic diagram illustrating the connection of the floor module to the floor module at C in FIG. 2;

FIG. 6 is a schematic diagram of the connection of the wallboard module to the wallboard module at D in FIG. 2;

FIG. 7 is a schematic diagram illustrating the connection of the roof module to the roof module at E in FIG. 2;

fig. 8 is a cross-sectional view of the viewing window at F in fig. 2.

In the figure: 1. an emergency stop switch; 2. a control screen of the closed cabin; 3. a sampling valve; 4. a power socket; 5. a glove; 6. an observation window; 7. a closed door; 8. a cladding plate; 10. a roof module; 12. a sealing valve; 13. a floor module; 15. an inner wallboard module; 17. an M8 bolt a; 18. a rubber gasket; 19. environmental protection sealant; 20. glass cement; 21. m8 lambda; 22. u-shaped door wrapping; 23. an M8 bolt b; 24. extruding a sheet; 25. square sealing sheets; 26. an M8 gasket; 27. an M8 bolt c; 28. tempered glass; 29. rubber U-shaped strips; 30. an outer frame of the observation window; 31. m4 bolts; 32. an observation window inner frame; 33. and a viewing window glass support frame.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments. All other embodiments obtained by those skilled in the art without making any inventive effort are within the scope of the present utility model.

Examples: a modular installation large-scale stainless steel airtight test cabin.

Referring to fig. 1 to 8, a modular installation large-sized stainless steel closed test chamber, comprising:

the bottom plate module 13, the bottom plate module 13 is formed by stainless steel square tube and corrosion resistant plate welding, and polylith bottom plate module 13 splice each other and form the cabin bottom surface, and the glass cement 20 has all been coated to the inboard of every bottom plate module 13 periphery square tube and corrosion resistant plate junction, has pasted fire prevention level hard extruded sheet 24 between the bottom surface of corrosion resistant plate in the bottom plate module 13 and the square tube, and the connection structure between the adjacent bottom plate module 13 is: the stainless steel plate of one bottom plate module 13 protrudes 2.5cm in square through, the square through of the other bottom plate module 13 protrudes 2.5cm in stainless steel plate, an environment-friendly sealant is applied to the joint of the stainless steel plate protruding from the bottom plate module 13 and the square through of the other bottom plate module 13, then the stainless steel plate protruding from the bottom plate module 13 is lapped on the square through protruding from the other bottom plate module 13, two adjacent bottom plate modules 13 are connected and fastened through M8 lamb and M8 bolts to form a sealing and fastening structure (figure 5), and other adjacent bottom plate modules 13 are sequentially sealed and fastened to form the bottom surface of the stainless steel closed test cabin product;

the inner wallboard module 15, the inner wallboard module 15 is formed by welding stainless steel plates, square tubes and reinforcing ribs, a circle of environment-friendly sealant is coated at the joint of the inner side of the square tube and the stainless steel plate of the inner wall, a through hole is formed in the square tube on the bottom surface of the inner wallboard module 15, the square tube is fixedly connected with a lambda 21 at the edge of the bottom plate module 13 through an M8 bolt 17 provided with a rubber gasket 18, an inner gap, which is in contact with the stainless steel plate on the bottom plate module 13, of the square tube on the bottom surface of the inner wallboard module 15 is coated with a low-release amount environment-friendly sealant 19, and a glass cement 20 is coated on the outer gap to form a seal (figure 4); a hexahedron is spliced between adjacent inner wall modules 14, stainless steel plates of the inner wall board modules 15 protrude out of square tubes by 2.5cm, environment-friendly sealant 19 is arranged at the joint of the protruding stainless steel plates and the square tubes, the stainless steel plates overlap with the protruding square tubes of the adjacent other inner wall board modules 15, M8 bolts 17 provided with rubber gaskets 18 pass through holes on the square tubes to be fixedly connected with lamb 21 on the square tubes of the inner wall board modules 15, meanwhile, low-release environment-friendly sealant 19 (figure 6) is arranged at the splicing inner joints of the two inner wall board modules 15, and glass cement 20 is arranged at the outer joints to form a seal;

the top plate module 10 is formed by welding stainless steel plates, square tubes and reinforcing ribs in a factory, a circle of glass cement is coated at the joint of the inner side of the square tube on the periphery and the stainless steel plates, the top plate module 10 is arranged at the top of the inner wall plate module 15, the M8 bolts 17 provided with rubber gaskets 18 penetrate through square through holes on the top surface of the inner wall plate module 15 and are fixedly connected with M8 lamb 21 on the square tube of the top plate module 10, glass cement 20 is coated at the outer connecting joint, and low-release environment-friendly sealant 19 is coated at the inner connecting joint to form sealing connection; the adjacent top plate modules 10 are fixedly connected with M8 lamb 21 on the adjacent top plate modules 10 through holes in the square of the top plate modules 10 by bolts 17 of M8 provided with rubber gaskets 18, the inner side is sewn with environment-friendly sealant 19 with low release amount, and the outer side is sewn with glass cement 20 (figure 7); sequentially splicing, fastening and sealing other top plate modules 10 to form the top surface of the stainless steel closed test cabin product;

the cladding board 8, cladding board 8 is formed by stainless steel square tube and corrosion resistant plate welding, and the adjacent cladding board 8 is through the bolt 17 and the M8 lambda 21 fastening connection of M8 that set up on each stainless steel square tube, the stainless steel square tube at cladding board 8 top is through the bolt 17 and the M8 lambda 21 fastening connection of M8 between the square tube that set up at interior wallboard module 15 top, the stainless steel square tube of cladding board 8 bottom is through the bolt 17 and the M8 lambda 21 fastening connection of M8 between the square tube that set up at interior wallboard module 15 bottom.

In actual installation, twelve inner wallboard modules 15 are spliced to form a hexahedral frame, three top board modules 10 are paved above the hexahedral frame formed by splicing the inner wallboard modules 15 in parallel, three bottom board modules 13 are installed below the hexahedral frame formed by splicing the inner wallboard modules 15 in parallel, then an external hanging board 8 is installed on the left side face, the right side face, the rear side face and the front side face of the hexahedral frame formed by splicing the inner wallboard modules 15, and finally an emergency stop switch 1, a touch screen 2, a sampling valve 3, a power socket 4, a glove 5, an observation window 6, a sealing door 7 and a sealing valve 12 and connecting cables are correspondingly installed on the external hanging board 8 installed on the front side face of the hexahedral frame to form the stainless steel sealing test cabin capable of being installed in a rapid modularized mode. The observation window 6 consists of an inner observation window frame 32, a rubber U-shaped strip 29, toughened glass 28, an outer observation window frame 30 and an outer observation window glass supporting frame 33; the observation window glass supporting frame 33 is welded on the stainless steel plate of the cladding plate 8, the toughened glass 28 is mounted on the observation window glass supporting frame 33 in a fit manner through the rubber U-shaped strips 29, the observation window inner frame 32 is fixed on the inner side of the observation window glass supporting frame 33 through the M4 bolts 31, the observation window outer frame 30 is fixed on the outer side of the observation window glass supporting frame 33 through the M4 bolts 31, and the environment-friendly sealant 19 or the glass cement 20 with low release amount is sprayed on the connecting joint of each part in the mounting process, so that the sealed observation window 6 is formed.

The modularized installation large-scale stainless steel airtight test cabin is simple in structure and reasonable in design, the stainless steel plates and the square tubes are modularized to form the top plate module 10, the bottom plate module 13, the inner wall plate module 15 and the outer hanging plate 8, and during factory modularized production and actual installation, the inner wall plate module 15, the top plate module 10, the bottom plate module 13 and the outer hanging plate 8 are only required to be assembled quickly according to design requirements, and the environment-friendly sealant is matched, so that the high-tightness stainless steel airtight cabin body is formed, the installation efficiency is improved, and the installation cost is reduced.

The foregoing is a preferred embodiment of the present utility model, but the present utility model should not be limited to the embodiment and the disclosure of the drawings, so that the equivalents and modifications can be made without departing from the spirit of the disclosure.

Claims (6)

1. A modular installation large stainless steel closed test chamber, comprising: the intelligent monitoring system comprises a plurality of top plate modules, a plurality of bottom plate modules, a plurality of inner wall plate modules and a plurality of cladding plates, wherein the plurality of top plate modules, the plurality of bottom plate modules, the plurality of inner wall plate modules and the plurality of cladding plates are arranged in a modular manner, the plurality of top plate modules are spliced between the plurality of inner wall plate modules to form a hexahedral frame, the plurality of top plate modules are parallelly arranged below the hexahedral frame formed by splicing the inner wall plate modules, the cladding plates are arranged on the left side surface, the right side surface, the rear side surface and the front side surface of the hexahedral frame formed by splicing the inner wall plate modules, and the cladding plates arranged on the front side surface of the hexahedral frame are correspondingly provided with an emergency stop switch, a closed cabin control screen, a sampling valve, a power socket, gloves, an observation window and a closed door.

2. The modular mounted large scale stainless steel containment test pod of claim 1, wherein: the inner wallboard modules are formed by welding stainless steel plates, square tubes and reinforcing ribs, the joints of the inner sides of the square tubes and the stainless steel plates are coated with environment-friendly sealant, and adjacent inner wallboard modules are connected through bolts and lamb fastening arranged on the square tubes.

3. The modular mounted large scale stainless steel containment test pod of claim 2, wherein: the bottom plate module is formed by welding a stainless steel square tube and a stainless steel plate, glass cement is coated at the joint of the inner side of the square tube and the stainless steel plate, the adjacent bottom plate modules are connected through bolts and lambda fastening arranged on the stainless steel square tube respectively, and the stainless steel square tube on the bottom plate module is connected with the square tube arranged at the bottom of the inner wall plate module through bolts and lambda fastening.

4. A modular mounted large scale stainless steel containment test pod as defined in claim 3, wherein: the roof module is formed by welding a stainless steel plate, square tubes and reinforcing ribs, glass cement is coated at the joint of the inner sides of the square tubes and the stainless steel plate, the adjacent roof modules are connected through bolts and lambda fastening arranged on the square tubes respectively, and the square tubes on the roof module are connected with the square tubes arranged on the top of the inner wallboard module through bolts and lambda fastening.

5. The modular mounted large scale stainless steel containment test pod of claim 4, wherein: the cladding board is formed by welding stainless steel square tubes and stainless steel plates, adjacent cladding boards are connected through bolts and lamb fastening arranged on the stainless steel square tubes, the stainless steel square tubes at the top of the cladding board are connected with the square tubes arranged at the top of the inner wallboard module through bolts and lamb fastening, and the stainless steel square tubes at the bottom of the cladding board are connected with the square tubes arranged at the bottom of the inner wallboard module through bolts and lamb fastening.

6. The modular mounted large scale stainless steel containment test pod of claim 5, wherein: the observation window comprises an inner observation window frame, rubber U-shaped strips, toughened glass, an outer observation window frame and an observation window glass supporting frame, wherein the observation window glass supporting frame is welded in the cladding, the toughened glass is mounted on the observation window glass supporting frame in a fit mode through the rubber U-shaped strips, the inner observation window frame is fixed on the inner side of the observation window glass supporting frame through bolts, and the outer observation window frame is fixed on the outer side of the observation window glass supporting frame through bolts.