CN217030479U - Novel cold insulation pipe support - Google Patents

Abstract

The utility model provides a novel cold-insulating pipe support, it includes pipe clamp and lower pipe clamp, characterized by: the upper pipe clamp and the lower pipe clamp the metal protective layer, the self-adhesive aluminum foil composite moisture-proof layer and the cold insulation layer into a whole with the pipeline through the double-end stud, the self-fastening disc spring group and the fastening sleeve, the cold insulation layer is an inorganic composite cold insulation layer, the vertical and radial loads of the pipeline are transmitted to the lower pipe clamp and the base through the inorganic composite cold insulation layer, the axial load of the pipeline is transmitted to the lower pipe clamp and the base through the fixing box, and the radial and axial limiting parts are welded with the site foundation to realize the radial and axial limiting; the inorganic composite cold insulation layer can prevent external heat from entering a pipeline to cause temperature rise and pressure increase of a medium in the pipeline and bring cold loss and safety risk while insulating heat. The utility model has the characteristics of easy processing and forming, obvious production cycle advantage, simple and convenient installation on engineering site, high efficiency and the like.

Description

Novel cold-proof pipe support

Technical Field

The utility model belongs to the field of supports for low-temperature medium conveying pipelines, and particularly relates to various forms of cold insulation pipe supports for fluid conveying pipelines with various calibers (DN 15-DN 1600) under the working conditions of normal temperature to-200 ℃, wherein A-level fire prevention is realized by adopting a novel inorganic cold insulation material, and meanwhile, the heat conductivity coefficient of the inorganic cold insulation pipe supports is superior to that of a traditional PIR, and the cold insulation performance of the cold insulation pipe supports is improved.

Background

At present, the pipe bracket material of the cold insulation pipe bracket for the domestic low-temperature working condition pipeline is characterized in that: the method is characterized in that upper and lower semi-cylindrical polyurethane (PUR for short) or polyisocyanurate (PIR for short) are used as heat insulation materials of a cold insulation pipe support, longitudinal seam gaps of upper and lower semi-cylindrical cold insulation blocks are filled with superfine glass wool or foamed rubber plastic strips, the outer surfaces of the cold insulation blocks are coated with mastic or PAP aluminum foil damp-proof layers, metal protective layers and steel pipe clamps are adopted to clamp the damp-proof layers, inner retaining rings are welded on pipelines and outer retaining rings are welded on the inner sides of the pipe clamps, and grooves are formed in the cold insulation blocks to achieve the axial limiting effect.

The cold-insulating pipe bracket has the following disadvantages:

PUR or PIR is an organic foaming material, and in order to improve the flame retardant property of the PUR or PIR, a halogen flame retardant is added in the manufacturing process, so that the corrosion of a steel pipeline is increased, and the safety of the pipeline is influenced.

And 2, the PUR or PIR cold insulation material has certain attenuation in performance and increases heat loss when the service life of the material is prolonged at any time.

PUR or PIR is an organic high molecular polymer with carbon-carbon bond as a basic structure, a large amount of smoke and a plurality of extremely toxic gases released by decomposition can be generated after the fire is ignited, and a plurality of fire reports indicate that the casualties caused by burning the smoke and the toxic gases have a far higher casualty ratio than that caused by real burning.

PUR or PIR generates a large amount of waste after being produced, used and scrapped, and is generally treated by a landfill method, and then the PUR or PIR waste is found to be difficult to decompose by being buried by a landfill method. The high-temperature incineration generates a large amount of toxic gases such as CO, CO2, HCN, isocyanate and the like. The adoption of chemical recycling equipment has the disadvantages of high investment, high energy consumption, low recovery rate and low economy.

And 5, the PUR or PIR cold insulation block longitudinal seam sealing strip should be lost and omitted in the installation and use processes, so that the hidden danger of dew cooling is caused.

Gaps exist between the PUR or PIR cold insulation block and the pipeline and between the cold insulation block and the cold insulation block, and low-temperature contraction is asynchronous, so that hidden danger of dew cold is caused.

The moisture-proof effect of the PUR or PIR cold insulation pipe support has a large relation with construction quality, and the support is easily damaged in the installation process, so that the moisture-proof effect is reduced.

And 8, the PUR or PIR cold insulation pipe support has multiple mounting steps and is relatively complex to mount.

9. The axial bending resistance of the welding baffle ring is not enough, the axial bending resistance is realized by welding reinforcing ribs, the contact between the inner baffle ring and a pipeline cold insulation material is discontinuous, and the hidden danger of exposed cold exists easily. Meanwhile, the outer side of the cold insulation block is required to be grooved for embedding an outer baffle ring on the inner side of the pipe clamp, and the grooving of the cold insulation block influences the overall strength of the cold insulation block, reduces the effective cold insulation thickness and also has the hidden danger of exposed cold.

SUMMERY OF THE UTILITY MODEL

The utility model aims to design an inorganic composite fixed cold insulation pipe support aiming at the problems that the cold insulation performance of PUR or PIR used by the traditional cold insulation pipe support is reduced along with the increase of the service life, a cold insulation material is ignited and burnt to generate a large amount of harmful substances, and the scrapping is difficult to treat

The technical scheme disclosed by the utility model is as follows:

the utility model provides a novel cold-proof pipe support, it includes pipe clamp 1 and lower pipe clamp 7, characterized by: the upper pipe clamp 1 and the lower pipe clamp 7 clamp a metal protective layer 10, a self-adhesive aluminum foil composite moisture-proof layer 2 and a cold insulation layer 3 into a whole with a pipeline 11 through a stud 4, a self-fastening disc spring group 5 and a fastening sleeve 6, the cold insulation layer 3 is an inorganic composite cold insulation layer, the vertical and radial loads of the pipeline 11 are transmitted to the lower pipe clamp 7 and a base 8 through the inorganic composite cold insulation layer, the axial load of the pipeline 11 is transmitted to the lower pipe clamp 7 and the base 8 through a fixing box 12, and the radial and axial limiting is realized through a radial limiting piece 9 and an axial limiting piece 14 which are welded with an on-site foundation 15; the inorganic composite cold insulation layer 3 can prevent external heat from entering the pipeline 11 to cause the temperature rise and pressure increase of a medium in the pipeline to bring cold loss and safety risk while insulating heat.

The cold insulation layer 3 is tightly attached to the pipeline 11 to transmit the load of the pipeline to the base 8, so that the defects of large heat conductivity coefficient, low strength, multiple abutted seams, easiness in cracking, high construction difficulty and easiness in scratching the pipeline of other inorganic cold insulation materials are overcome.

The cold insulation layer 3 is formed by alternately compounding a powder-free aerogel felt layer and a deep cooling aerogel felt layer.

Stud 4, the tight dish spring group 5 of autogenous binding constitute fastening system, and stud or bolt cooperation flat shim and dish spring combination use, can both effectually provide continuously changeable clamp force under all kinds of operating modes, make inorganic compound cold insulation pipe support become one with pipeline 11, solved traditional fastening mode because of the low temperature shrink lead to cold insulation pipe support because of the not enough pipeline that leads to of clamp force and cold insulation pipe support slippage dew cold condition, guaranteed cold insulation system's continuity and integrality.

The fastening sleeve 6 enables the fastening force of the stud and the bolt to be close to the pipeline and easier to clamp, the situation that the fastening force is insufficient due to the fact that the traditional pipe clamp is bent or the strength and the rigidity of the welding lug plate are weak is avoided, and meanwhile the pipe clamp is more friendly and safer to install and use.

The fixing box 12 is compatible with the pipeline material, and the periphery of the fixing box is provided with low temperature resistant high-strength cold insulation blocks to avoid direct contact with the lower pipe clamp 7. The fixing boxes are divided into a bolt connection type and an adhesion type according to different fixing modes of the high-strength cold insulation block; the welding backing plate 12-1 of the bolted cold insulation block fixing box is welded with the bottom of a pipeline and is combined with a fixing box vertical plate 12-5 and a fixing box rib plate 12-6 to form a fixing box frame, and the high-strength cold insulation block 12-2 is integrated with the fixing box frame through an axial fastening structure 12-3 and a radial fastening structure 12-4; a welding backing plate 12-1 of the bonding type cold insulation block fixing box is welded with the bottom of a pipeline and is combined with a fixing box vertical plate 12-5 and a fixing box rib plate 12-6 to form a fixing box frame, and a high-strength cold insulation block 12-2 is integrated with the fixing box frame through a cryogenic adhesive.

The high-strength cold insulation block 12-2 is made of high-strength Parmali wood blocks, high-strength PIR blocks or high-strength FRP blocks in low-temperature-resistant and low-heat-conductive materials.

The beneficial effects of the utility model are:

the inorganic composite cold insulation pipe support has the advantages of optimal heat insulation performance, deep cooling, flexibility, low deformation, integral drainage, moisture prevention, integral fire prevention, non-combustibility, expansion joint-free design, simple and reliable structure, strong applicability, simple and efficient installation, long and stable performance, easy treatment, safety, environmental protection and the like.

Compared with the traditional cold insulation pipe support construction, the support is simpler and more convenient to install, has more excellent cold insulation performance, is an inorganic A-grade fireproof green environment-friendly material, and is suitable for supporting fluid conveying pipelines with various calibers (DN 15-DN 1600) under the low-temperature working conditions of normal temperature to-200 ℃ in various forms.

The fixing and limiting function of the inorganic composite cold-insulating pipe support is realized by adopting the fixing box with an innovative fixing structure.

Drawings

FIG. 1 is a radial schematic view of the structure of the inorganic composite fixed cold-insulating pipe bracket of the utility model.

Fig. 2 is a schematic structural axial view of the inorganic composite fixed cold-insulating pipe bracket.

Fig. 3 is a schematic illustration of the bolting of the high-strength adiabatic block of the fixing box according to the present invention.

FIG. 4 is a schematic diagram of the adhesion of the high strength cold insulation block of the fixing box of the present invention

In the figure: 1-upper pipe clamp, 2-self-adhesive composite moisture-proof layer, 3-inorganic composite cold insulation layer, 4-double-end stud, 5-self-tightening disc spring set, 6-fastening sleeve, 7-lower pipe clamp, 8-base, 9-radial limiting piece, 10-metal protective layer, 12-fixing box, 13-base cold insulation layer and 14-axial limiting piece.

Detailed Description

The utility model is further described below with reference to the figures and examples.

As shown in fig. 1-4.

A novel cold insulation pipe support comprises an upper pipe clamp 1, a self-adhesion composite moisture-proof layer 2, a cold insulation layer 3, a stud 4, a self-tightening disc spring set 5, a fastening sleeve 6, a lower pipe clamp 7, a base 8, a radial limiting part 9, a metal protective layer 10, a pipeline 11, a fixing box 12, an axial limiting part 14 and a field foundation 15. The upper pipe clamp and the lower pipe clamp the pipeline all the time through the self-tightening fastener under any working condition, and load is transmitted to the base through the inorganic composite cold insulation layer. The upper pipe clamp 1 and the lower pipe clamp 7 clamp a metal protective layer 10, a self-adhesive aluminum foil composite moisture-proof layer 2 and a cold insulation layer 3 into a whole with a pipeline 11 through a stud 4, a self-fastening disc spring group 5 and a fastening sleeve 6, the cold insulation layer 3 is an inorganic composite cold insulation layer, the vertical and radial loads of the pipeline 11 are transmitted to the lower pipe clamp 7 and a base 8 through the inorganic composite cold insulation layer, the axial load of the pipeline 11 is transmitted to the lower pipe clamp 7 and the base 8 through a fixing box 12, and the radial and axial limiting is realized through a radial limiting piece 9 and an axial limiting piece 14 which are welded with an on-site foundation 15; the inorganic composite cold insulation layer 3 can prevent external heat from entering the pipeline 11 to cause the temperature rise and pressure increase of a medium in the pipeline to bring cold loss and safety risk while insulating heat. As shown in fig. 1 and 2.

The structure and the function of the innovative cold insulation system are as follows: the cold insulation layer 3 of the utility model adopts inorganic nano aerogel felt as cold insulation material, thus thoroughly solving the defects of PUR or PIR cold insulation material. And is formed by alternately compounding a powder-free aerogel felt layer and a deep cooling aerogel felt layer. The inorganic composite cold insulation layer 3 has the lowest heat conductivity coefficient of all low-temperature cold insulation material substitution varieties, and can reduce heat absorption and medium evaporation in a pipeline to the maximum extent. The same cold insulation effect is achieved, the cold insulation thickness is only half of that of the traditional PUR or PIR cold insulation material, and the weight is lighter. The inorganic nanometer aerogel felt cold insulation material is hydrophobic, and can prevent water vapor in the environment from entering the cold insulation material. The inorganic nanometer aerogel felt cold insulation material can keep flexibility under the deep cooling working condition, so that the requirement of the expansion joint of the traditional cold insulation structure is avoided, the installation is simplified, and the installation speed is accelerated. The inorganic nanometer aerogel felt cold insulation material has excellent heat insulation performance, sound insulation performance and fireproof performance, and achieves A-level fireproof performance.

When the pipeline 11 is wrapped, the self-adhesive composite moisture-proof layer 2 is adopted, the use temperature range is-41-160 ℃, the water vapor permeability is 0, the self-adhesive composite moisture-proof layer is composed of a protective plastic film layer, a cryogenic mastic grease layer and a PAP aluminum foil from inside to outside, and the self-adhesive composite moisture-proof pipeline is simple and convenient to install, efficient and excellent in performance.

The utility model adopts the innovative fastening sleeve, the stud and the self-tightening disc spring to form a sleeving design, increases the fastening strength and the rigidity of the pipe clamp, reduces the overall dimension of the pipe bracket, achieves the fastening effect under any working condition, and is safe and reliable.

By adopting the innovative design of the fixing box 12, the fixing problem of the inorganic composite cold insulation pipe support is solved, and the defects of the fixing structure of the traditional cold insulation pipe support are overcome. As shown in fig. 3 and 4. The innovative fixing box 12 is adopted, the fixing and limiting effects of the cold insulation pipe support are realized, and the structure is safe and reliable.

The fixing box 12 is compatible with the pipeline material, and the periphery of the fixing box is provided with low temperature resistant high-strength cold insulation blocks to avoid direct contact with the lower pipe clamp 7. The fixing boxes are classified into a bolt type shown in fig. 3 and an adhesive type shown in fig. 4 according to the fixing manner of the high-strength adiabatic block. As shown in figure 3, a welding backing plate 12-1 of the bolted cold insulation block fixing box is welded with the bottom of a pipeline and is combined with a fixing box vertical plate 12-5 and a fixing box rib plate 12-6 to form a fixing box framework, and a high-strength cold insulation block 12-2 is integrated with the fixing box framework through an axial fastening structure 12-3 and a radial fastening structure 12-4. As shown in figure 4, a welding backing plate 12-1 of the adhesive type cold insulation block fixing box is welded with the bottom of a pipeline and is combined with a fixing box vertical plate 12-5 and a fixing box rib plate 12-6 to form a fixing box framework, and a high-strength cold insulation block 12-2 is integrated with the fixing box framework through a cryogenic adhesive. The high-strength cold insulation block 12-2 is made of a high-strength Palmali wood block, a high-strength PIR block or a high-strength FRP block in low-temperature-resistant low-heat-conducting materials.

The utility model starts from two aspects of cold insulation material design and cold insulation structure design, on one hand, the inorganic nanometer aerogel felt for deep cooling is adopted, the innovative cold insulation pipe bracket has the lowest heat conductivity coefficient (0.0137W/m.K at minus 170 ℃, 0.017W/m.K at 23 ℃, inorganic A-grade fire prevention and the best heat insulation performance and has the non-combustible performance, on the other hand, the innovative cold insulation structure design is adopted, a fixed box structure is innovatively adopted, the whole hydrophobic block water vapor invasion in the environment, and the expansion joint has flexibility from the normal temperature to the deep cooling working condition, the requirement on the cold insulation layering is eliminated, the cold insulation layering is consistent with the pipe cold insulation layering, the tight combination can be realized, and the fastening is more reliable by adopting the innovative fastening design.

The weight of inorganic compound cold insulation pipe support only is 40% ~55% of traditional cold insulation pipe support weight, and the volume size is about 70% of traditional cold insulation pipe support, and the condition that traditional cold insulation piece is damaged, the installation lacks the piece can not appear at the in-process of transportation storage installation, in addition, because light-weighted design, the workman is under construction more conveniently, and engineering installation progress can improve more than 70%.

The utility model is not related in part to or can be practiced using the prior art.

Claims (6)

1. The utility model provides a novel cold-insulating pipe support, it includes pipe clamp (1) and lower tube clamp (7), characterized by: the upper pipe clamp (1) and the lower pipe clamp (7) clamp a metal protective layer (10), a self-adhesive aluminum foil composite moisture-proof layer (2) and a cold insulation layer (3) into a whole with a pipeline (11) through a stud (4), a self-tightening disc spring group (5) and a fastening sleeve (6), the cold insulation layer (3) is an inorganic composite cold insulation layer, the vertical and radial loads of the pipeline (11) are transmitted to the lower pipe clamp (7) and a base (8) through the inorganic composite cold insulation layer, the axial load of the pipeline (11) is transmitted to the lower pipe clamp (7) and the base (8) through a fixing box (12), and the radial and axial limiting is realized through a radial limiting piece (9) and an axial limiting piece (14) which are welded with a site foundation (15); the inorganic composite cold insulation layer (3) can prevent external heat from entering the pipeline (11) to cause the increase of the temperature and the pressure of a medium in the pipeline, thereby bringing cold loss and safety risk.

2. The novel cold-insulating pipe support of claim 1, wherein: the cold insulation layer (3) is tightly attached to the pipeline (11) so as to transmit the load of the pipeline to the base (8).

3. The novel cold insulation pipe support according to claim 1 or 2, characterized in that: the cold insulation layer (3) is formed by alternately compounding a powder-free aerogel felt layer and a deep cooling aerogel felt layer.

4. The novel cold-insulating pipe support of claim 1, wherein: the double-end stud (4) and the self-tightening disc spring group (5) form a fastening system, the double-end stud or the bolt is matched with the flat gasket and the disc spring for combined use, and the continuous and variable clamping force can be effectively provided under various working conditions, so that the inorganic composite cold insulation pipe support and the pipeline (11) are integrated.

5. A novel cold-insulating tube support according to claim 1, characterized in that: the fixing box (12) is compatible with the pipeline material, and the periphery of the fixing box is provided with low-temperature-resistant high-strength cold insulation blocks to avoid direct contact with the lower pipe clamp (7); the fixing box is divided into a bolt connection type and an adhesion type according to different fixing modes of the high-strength cold insulation block; a welding backing plate (12-1) of the bolted cold insulation block fixing box is welded with the bottom of the pipeline, and is combined with a fixing box vertical plate (12-5) and a fixing box rib plate (12-6) to form a fixing box frame, and a high-strength cold insulation block (12-2) is integrated with the fixing box frame through an axial fastening structure (12-3) and a radial fastening structure (12-4); a welding backing plate (12-1) of the adhesive type cold insulation block fixing box is welded with the bottom of a pipeline, and is combined with a fixing box vertical plate (12-5) and a fixing box rib plate (12-6) to form a fixing box frame, and a high-strength cold insulation block (12-2) is integrated with the fixing box frame through a cryogenic adhesive.

6. The novel cold-storage tube support of claim 5, wherein: the high-strength cold insulation block (12-2) is made of a high-strength Parmarie block, a high-strength PIR block or a high-strength FRP block in low-temperature-resistant and low-heat-conductive materials.

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