CN213040088U

CN213040088U - Module structure of calcium silicate thermal insulation pipe shell

Info

Publication number: CN213040088U
Application number: CN202021836203.1U
Authority: CN
Inventors: 裘益奇; 雷泉兴; 裘茂法; 卢建军; 樊嵘
Original assignee: Zhejiang Aske Building Materials Technology Corp
Current assignee: Zhejiang Aske Building Materials Technology Corp
Priority date: 2020-08-28
Filing date: 2020-08-28
Publication date: 2021-04-23
Anticipated expiration: 2030-08-28

Abstract

The utility model discloses a modular structure of calcium silicate insulation tube, including pasting the insulation component who applies at the pipeline surface, the both ends of pipeline are equipped with fixed subassembly, and insulation component is located between the fixed subassembly, fixedly connected with inoxidizing coating in the fixed subassembly, and the surface at insulation component is hugged closely to the inboard of inoxidizing coating. The utility model discloses an applying the insulation assembly at the outer surface of pipeline subsides, simultaneously at the fixed subassembly of both ends installation of pipeline, the insulation assembly sets up between fixed subassembly, install the inoxidizing coating in fixed subassembly after that, the inboard of inoxidizing coating pastes tight insulation assembly, the inoxidizing coating plays a guard action to insulation assembly, the setting of fixed subassembly plays a fixed action to the inoxidizing coating, make the inoxidizing coating fix in insulation assembly's the outside, thereby avoided producing between insulation assembly and the pipeline and broken away from, simultaneously with the pipeline, insulation assembly and inoxidizing coating form a whole, the whole of heat preservation tube has been improved, thereby the heat preservation effect of heat preservation tube has been increased.

Description

Module structure of calcium silicate thermal insulation pipe shell

Technical Field

The utility model belongs to the technical field of the pipeline keeps warm, concretely relates to calcium silicate insulation tube's modular structure.

Background

The steam pipeline is one of heat distribution pipelines and is mainly used for heating, ventilation, air conditioning steam, industrial gas and the like. The heat preservation of the steam pipeline is vital, and if heat preservation measures are not taken, the heat loss is extremely large.

The existing thermal insulation pipe shell is generally formed into a cylindrical structure by overlapping two half parts in a staggered manner, and is used for wrapping the outer surface of a heating pipeline: half including high-efficient heat preservation and ordinary heat preservation, the internal surface of high-efficient heat preservation is used for laminating mutually with the outer wall of pipeline, and the surface of high-efficient heat preservation laminates mutually with the internal surface of ordinary heat preservation, but discovery when in-service use, the insulation tube shell structure is fragile, and relative slip appears between high-efficient heat preservation and the ordinary heat preservation easily, leads to the wholeness of insulation tube shell structure relatively poor to the heat preservation effect of insulation tube shell has been reduced.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the above-mentioned technical problem that exists among the prior art, the utility model provides a calcium silicate insulation tube's modular structure, through applying the insulation assembly at the outer surface of pipeline subsides, simultaneously at the both ends installation fixed subassembly of pipeline, the insulation assembly sets up between fixed subassembly, install the inoxidizing coating in fixed subassembly after that, the inboard of inoxidizing coating pastes tight insulation assembly, the inoxidizing coating plays a guard action to insulation assembly, fixed subassembly's setting plays a fixed action to the inoxidizing coating, make the inoxidizing coating fix the outside at insulation assembly, thereby avoided producing between insulation assembly and the pipeline and break away from, simultaneously with the pipeline, insulation assembly forms a whole with the inoxidizing coating, the whole of insulation tube has been improved, thereby the heat preservation effect of insulation tube has been increased.

In order to solve the technical problem, the utility model discloses a following technical scheme:

a modular structure of calcium silicate insulation pipe shell, which comprises an insulation component applied on the outer surface of a pipeline, and is characterized in that: the pipeline is characterized in that fixing assemblies are arranged at two ends of the pipeline, the heat insulation assembly is located between the fixing assemblies, a protective layer is fixedly connected in the fixing assemblies, and the inner side of the protective layer is tightly attached to the outer surface of the heat insulation assembly. The utility model discloses an applying the insulation assembly at the outer surface of pipeline subsides, simultaneously at the fixed subassembly of both ends installation of pipeline, the insulation assembly sets up between fixed subassembly, install the inoxidizing coating in fixed subassembly after that, the inboard of inoxidizing coating pastes tight insulation assembly, the inoxidizing coating plays a guard action to insulation assembly, the setting of fixed subassembly plays a fixed action to the inoxidizing coating, make the inoxidizing coating fix in insulation assembly's the outside, thereby avoided producing between insulation assembly and the pipeline and broken away from, simultaneously with the pipeline, insulation assembly and inoxidizing coating form a whole, the whole of heat preservation tube has been improved, thereby the heat preservation effect of heat preservation tube has been increased.

Further, the heat preservation subassembly includes high-efficient heat preservation and ordinary heat preservation, and the surface at the pipeline is applied in the subsides of high-efficient heat preservation, and ordinary heat preservation is applied in the surface of high-efficient heat preservation. The heat preservation effect of the heat preservation pipe shell is improved by arranging the high-efficiency heat preservation layer and the common heat preservation layer.

Furthermore, the high-efficiency heat-insulating layer and the common heat-insulating layer are both formed by staggering and laminating. The temperature of the pipeline is firmly locked and fixed in the high-efficiency heat insulation layer and the common heat insulation layer, so that the heat loss is greatly reduced, and the heat insulation effect is greatly improved.

Further, fixed subassembly includes the fixing base, fixed lid and 4 at least threaded rods, and the fixing base welding is in the one end of pipeline, and 4 at least threaded rod circumference distribute is close to the one end at pipeline center at the fixing base, threaded rod and fixing base welded connection, and the inoxidizing coating passes the threaded rod, and the one end of inoxidizing coating supports on the fixing base, and fixed lid is equipped with the step hole, and the threaded rod passes the step hole, and the other end of inoxidizing coating supports and covers fixedly, and the threaded rod is equipped with the nut, and the nut is screwed up. Weld the fixing base in the one end of pipeline earlier, install the thermal insulation component on the pipeline again, then weld the threaded rod on the fixing base again, penetrate the inoxidizing coating along the threaded rod after that, make the one end of inoxidizing coating support on the fixing base, penetrate the threaded rod with fixed lid after that, make the threaded rod be located the step hole, twist the nut on the threaded rod at last, make the nut tighten the step hole again, thereby accomplish the installation, the setting of threaded rod plays a guide effect and guide effect to the installation of inoxidizing coating, the threaded rod passes the inoxidizing coating simultaneously and has still increased the bearing capacity of inoxidizing coating, the threaded rod protrusion in the outside of fixed lid has been avoided in establishing of step hole, the dismouting of inoxidizing coating.

Further, the inoxidizing coating is formed by 4 at least protection pieces concatenations, and the quantity of protection piece is the same with the quantity of threaded rod. The protective layer is spliced by the protective blocks, when the protective layer is damaged, only the protective block which is damaged by heavy is needed to be replaced singly, the whole protective layer is not needed to be replaced, and resources are greatly saved.

Further, the one end of protection piece is equipped with the slider, and the other end of protection piece is equipped with the spout, slider and spout phase-match, and the center of protection piece is equipped with the through-hole, and the threaded rod passes the through-hole. The protection piece is in the installation, and adjacent protection piece top shoe inserts along the spout of another piece to accomplish the concatenation, the setting up of slider and spout has improved the wholeness of inoxidizing coating, thereby has improved the bearing capacity of inoxidizing coating.

Furthermore, the inner side of the protection block is provided with an elastic cushion block, and the elastic cushion block is tightly attached to the outer surface of the heat preservation assembly. The heat insulation assembly on the inner side of the protection block is prevented from being damaged by the outside stress of the protection block, the protection cushion block plays a role in buffering, and the heat insulation assembly is prevented from being damaged.

Furthermore, the outer edges of the ends, close to the center of the pipeline, of the fixed seat and the fixed cover are provided with extension blocks, and the extension blocks are tightly attached to the outer surface of the protective layer. The extension block is clamped on the outer surface of the protective layer to limit the protective layer.

The utility model discloses owing to adopted above-mentioned technical scheme, following beneficial effect has:

the utility model discloses an applying the insulation assembly at the outer surface of pipeline subsides, simultaneously at the fixed subassembly of both ends installation of pipeline, the insulation assembly sets up between fixed subassembly, install the inoxidizing coating in fixed subassembly after that, the inboard of inoxidizing coating pastes tight insulation assembly, the inoxidizing coating plays a guard action to insulation assembly, the setting of fixed subassembly plays a fixed action to the inoxidizing coating, make the inoxidizing coating fix in insulation assembly's the outside, thereby avoided producing between insulation assembly and the pipeline and broken away from, simultaneously with the pipeline, insulation assembly and inoxidizing coating form a whole, the whole of heat preservation tube has been improved, thereby the heat preservation effect of heat preservation tube has been increased.

The utility model discloses well fixed subassembly includes fixing base, fixed lid and 4 at least threaded rods, and the fixing base welding is in the one end of pipeline, and 4 at least threaded rod circumference distributes and is close to the one end at pipeline center at the fixing base, threaded rod and fixing base welded connection, and the inoxidizing coating passes the threaded rod, and the one end of inoxidizing coating supports on the fixing base, and fixed lid is equipped with the step hole, and the threaded rod passes the step hole, and the other end of inoxidizing coating supports and covers fixedly, and the threaded rod is equipped with the nut, and the nut is. Weld the fixing base in the one end of pipeline earlier, install the thermal insulation component on the pipeline again, then weld the threaded rod on the fixing base again, penetrate the inoxidizing coating along the threaded rod after that, make the one end of inoxidizing coating support on the fixing base, penetrate the threaded rod with fixed lid after that, make the threaded rod be located the step hole, twist the nut on the threaded rod at last, make the nut tighten the step hole again, thereby accomplish the installation, the setting of threaded rod plays a guide effect and guide effect to the installation of inoxidizing coating, the threaded rod passes the inoxidizing coating simultaneously and has still increased the bearing capacity of inoxidizing coating, the threaded rod protrusion in the outside of fixed lid has been avoided in establishing of step hole, the dismouting of inoxidizing coating.

Drawings

The present invention will be further explained with reference to the accompanying drawings:

fig. 1 is a schematic structural diagram of a modular structure of a calcium silicate insulation pipe shell according to the present invention;

FIG. 2 is a schematic view of the connection structure of the heat-insulating assembly and the pipeline;

FIG. 3 is a schematic view of the connection between the fixing base and the threaded rod of the present invention;

fig. 4 is a schematic structural view of the fixing cover of the present invention;

fig. 5 is a schematic structural diagram of the protective layer of the present invention.

In the figure, 1-pipe; 2-a heat preservation component; 3-a fixing component; 4-a protective layer; 5-high-efficiency heat insulation layer; 6-common insulating layer; 7-a fixed seat; 8-fixing the cover; 9-a threaded rod; 10-a stepped bore; 11-a nut; 12-a guard block; 13-a slide block; 14-a chute; 15-elastic cushion blocks; 16-an extension block; 17-through hole.

Detailed Description

As shown in fig. 1 to 5, for the utility model relates to a modular structure of calcium silicate insulation tube shell, including pasting the insulation component 2 who applies at 1 surface of pipeline, the both ends of pipeline 1 are equipped with fixed subassembly 3, and insulation component 2 is located between the fixed subassembly 3, and fixedly connected with inoxidizing coating 4 in the fixed subassembly 3, the surface at insulation component 2 is hugged closely to the inboard of inoxidizing coating 4.

The heat preservation assembly 2 comprises a high-efficiency heat preservation layer 5 and a common heat preservation layer 6, wherein the high-efficiency heat preservation layer 5 is attached to the outer surface of the pipeline 1, and the common heat preservation layer 6 is attached to the outer surface of the high-efficiency heat preservation layer 5. The heat preservation effect of the heat preservation pipe shell is improved by arranging the high-efficiency heat preservation layer 5 and the common heat preservation layer 6.

The high-efficiency heat-insulating layer 5 and the common heat-insulating layer 6 are both formed by staggering and stacking. The temperature of the pipeline 1 is firmly locked and fixed in the high-efficiency heat-insulating layer 5 and the common heat-insulating layer 6, so that the heat loss is greatly reduced, and the heat-insulating effect is greatly improved.

Fixed subassembly 3 includes fixing base 7, fixed lid 8 and 4 at least threaded rods 9, the welding of fixing base 7 is in the one end of pipeline 1, 9 circumference distributions of 4 at least threaded rods are close to the one end at 1 center of pipeline at fixing base 7, threaded rod 9 and 7 welded connection of fixing base, inoxidizing coating 4 passes threaded rod 9, the one end of inoxidizing coating 4 supports on fixing base 7, fixed lid 8 is equipped with step hole 10, threaded rod 9 passes step hole 10, the other end of inoxidizing coating 4 supports on fixed lid 8, threaded rod 9 is equipped with nut 11, nut 11 screws up in step hole 10. Weld fixing base 7 in the one end of pipeline 1 earlier, install heat preservation subassembly 2 on pipeline 1 again, then weld threaded rod 9 on fixing base 7 again, penetrate inoxidizing coating 4 along threaded rod 9 after that, make inoxidizing coating 4's one end support on fixing base 7, penetrate threaded rod 9 with fixed lid 8 after that, make threaded rod 9 be located step hole 10, screw into threaded rod 9 with nut 11 at last, make nut 11 screw up in step hole 10 again, thereby accomplish the installation, setting up of threaded rod 9 plays a guide effect and guide effect to inoxidizing coating 4's installation, threaded rod 9 passes inoxidizing coating 4 simultaneously and has still increased the bearing capacity of inoxidizing coating 4, establish of step hole 10 has avoided threaded rod 9 to bulge in the outside of fixed lid 8, the dismouting of inoxidizing coating 4 is simple, swiftly has been realized.

The protective layer 4 is formed by splicing at least 4 protective blocks 12, and the number of the protective blocks 12 is the same as that of the threaded rods 9. The protective layer 4 is spliced by the protective blocks 12, when the protective layer 4 is damaged, only the protective block 12 which is damaged heavily is needed to be replaced singly, the whole protective layer 4 is not needed to be replaced, and resources are greatly saved.

One end of the protection block 12 is provided with a sliding block 13, the other end of the protection block 12 is provided with a sliding groove 14, the sliding block 13 is matched with the sliding groove 14, the center of the protection block 12 is provided with a through hole 17, and the threaded rod 9 penetrates through the through hole 17. In the installation process of the protective blocks 12, the sliding blocks 13 on the adjacent protective blocks 12 are inserted along the sliding grooves 14 on the other protective blocks, so that splicing is completed, the integrity of the protective layer 4 is improved due to the arrangement of the sliding blocks 13 and the sliding grooves 14, and the bearing capacity of the protective layer 4 is improved.

The inner side of the protection block 12 is provided with an elastic cushion block 15, and the elastic cushion block 15 is tightly attached to the outer surface of the heat preservation component 2. The heat insulation component 2 on the inner side of the protection block 12 is prevented from being damaged by the outside stress of the protection block 12, the protection cushion block plays a role in buffering, and the heat insulation component 2 is prevented from being damaged.

The outer edges of the fixed seat 7 and the fixed cover 8 close to the center of the pipeline 1 are provided with extension blocks 16, and the extension blocks 16 are tightly attached to the outer surface of the protective layer 4. The extension block 16 is clamped on the outer surface of the protective layer 4 to limit the protective layer 4.

The utility model discloses an applying insulation assembly 2 at 1 surface subsides of pipeline, simultaneously at the fixed subassembly 3 of both ends installation of pipeline 1, insulation assembly 2 sets up between fixed subassembly 3, install inoxidizing coating 4 in fixed subassembly 3 after that, the tight insulation assembly 2 of inboard subsides of inoxidizing coating 4, inoxidizing coating 4 plays a guard action to insulation assembly 2, the setting of fixed subassembly 3 plays a fixed action to inoxidizing coating 4, make inoxidizing coating 4 fix the outside at insulation assembly 2, thereby avoided producing between insulation assembly 2 and the pipeline 1 and break away from, simultaneously with pipeline 1, insulation assembly 2 forms a whole with inoxidizing coating 4, the whole of heat preservation tube has been improved, thereby the heat preservation effect of heat preservation tube has been increased.

The above is only a specific embodiment of the present invention, but the technical features of the present invention are not limited thereto. Any simple changes, equivalent substitutions or modifications made on the basis of the present invention to solve the same technical problems and achieve the same technical effects are all covered by the protection scope of the present invention.

Claims

1. A modular structure of calcium silicate insulation pipe shell, which comprises an insulation component applied on the outer surface of a pipeline, and is characterized in that: the pipeline heat insulation structure is characterized in that fixing assemblies are arranged at two ends of the pipeline, the heat insulation assembly is located between the fixing assemblies, a protective layer is fixedly connected in the fixing assemblies, and the inner side of the protective layer is tightly attached to the outer surface of the heat insulation assembly.

2. The modular structure of a calcium silicate insulating shell as claimed in claim 1, wherein: the heat preservation assembly comprises a high-efficiency heat preservation layer and a common heat preservation layer, the high-efficiency heat preservation layer is attached to the outer surface of the pipeline, and the common heat preservation layer is attached to the outer surface of the high-efficiency heat preservation layer.

3. The modular structure of a calcium silicate insulating shell as claimed in claim 2, wherein: the high-efficiency heat-insulating layer and the common heat-insulating layer are both formed by staggering and stacking.

4. The modular structure of a calcium silicate insulating shell as claimed in claim 2, wherein: the high-efficiency heat-insulating layer is bonded with the common heat-insulating layer through high-temperature inorganic glue.

5. The modular structure of a calcium silicate insulating shell as claimed in claim 1, wherein: the fixed subassembly includes fixing base, fixed lid and 4 at least threaded rods, the fixing base welding is in the one end of pipeline, 4 at least threaded rod circumference distributes the fixing base is close to the one end at pipeline center, the threaded rod with fixing base welded connection, the inoxidizing coating passes the threaded rod, the one end of inoxidizing coating supports on the fixing base, fixed lid is equipped with the step hole, the threaded rod passes the step hole, the other end of inoxidizing coating supports on the fixed lid, the threaded rod is equipped with the nut, the nut is screwed up in the step hole.

6. The modular structure of a calcium silicate insulating shell as claimed in claim 5, wherein: the inoxidizing coating is formed by 4 at least protection pieces concatenations, the quantity of protection piece with the quantity of threaded rod is the same.

7. The modular structure of a calcium silicate insulating shell as claimed in claim 6, wherein: the one end of protection piece is equipped with the slider, the other end of protection piece is equipped with the spout, the slider with the spout phase-match, the center of protection piece is equipped with the through-hole, the threaded rod passes the through-hole.

8. The modular structure of a calcium silicate insulating shell as claimed in claim 6, wherein: and an elastic cushion block is arranged on the inner side of the protection block and clings to the outer surface of the heat insulation component.

9. The modular structure of a calcium silicate insulating shell as claimed in claim 5, wherein: the outer edge of one end of the fixed seat and the fixed cover close to the center of the pipeline is provided with an extension block, and the extension block is tightly attached to the outer surface of the protective layer.