CN217272481U - Wind power cooling pipe - Google Patents
Wind power cooling pipe Download PDFInfo
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- CN217272481U CN217272481U CN202220152246.0U CN202220152246U CN217272481U CN 217272481 U CN217272481 U CN 217272481U CN 202220152246 U CN202220152246 U CN 202220152246U CN 217272481 U CN217272481 U CN 217272481U
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
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- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
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Abstract
The utility model provides a wind-powered electricity generation cooling tube has set gradually from inside to outside: the ethylene propylene diene monomer inner rubber layer is 1-5mm thick; the thickness of the polyester fiber woven fiber layer is 1-3 mm; the thickness of the polyvinyl chloride outer adhesive layer is 1-5 mm. The wind power cooling pipe is simple in structure and reasonable in design, and has good low permeability, low extraction, high strength, flame retardance, static resistance, aging resistance, abrasion resistance, high temperature resistance, low temperature resistance, weather resistance, mildew resistance and flexibility through the cooperative matching of the layers.
Description
Technical Field
The utility model relates to a cooling tube, concretely relates to wind-powered electricity generation cooling tube.
Background
With the rapid development of global economy, the demand of electric energy is increased, but the attention of people on green environment is increased while the economy is developed, and wind power generation is regarded as a high-efficiency green environment-friendly power generation mode and is emphasized by the nation and the society, so that the rapid development is achieved in recent years. The wind power cooling liquid pipeline is used as an important part on the wind power generator and is mainly used for conveying cooling liquid to cool the wind power generator. And present traditional wind-powered electricity generation coolant liquid pipeline generally adopts copper metal pipeline, and not only manufacturing cost is high, and the flexibility is poor, and the piping erection is difficult, and the constant temperature performance is poor moreover, takes place the infiltration weeping easily, has certain limitation to the installation environment, consequently needs the improvement.
SUMMERY OF THE UTILITY MODEL
Not enough to prior art, the utility model provides a wind-powered electricity generation cooling tube has good hyposmosis, low taking out, intensity is high, fire-retardant, antistatic, ageing-resistant performance and wear resistance can.
In order to realize the technical scheme, the utility model provides a wind-powered electricity generation cooling tube has set gradually from inside to outside: the ethylene propylene diene monomer inner rubber layer is 1-5mm thick; the thickness of the polyester fiber woven fiber layer is 1-3 mm; the thickness of the polyvinyl chloride outer adhesive layer is 1-5 mm.
Preferably, the thickness of the ethylene propylene diene monomer inner rubber layer is 1-3mm, the thickness of the polyester fiber woven fiber layer is 1-2mm, and the thickness of the polyvinyl chloride outer rubber layer is 1-3 mm.
Preferably, the thickness of the ethylene propylene diene monomer inner rubber layer is 2mm, the thickness of the polyester fiber woven fiber layer is 1mm, and the thickness of the polyvinyl chloride outer rubber layer is 2 mm.
The utility model also provides a wind-powered electricity generation cooling tube has set gradually from inside to outside: the ethylene propylene diene monomer inner rubber layer is 1-5mm thick; the thickness of the polyester fiber woven fiber layer is 1-3 mm; a thermoplastic vulcanizate anti-deformation layer having a thickness of 2-6 mm; the thickness of the polyvinyl chloride outer adhesive layer is 1-5 mm.
Preferably, the thickness of the ethylene propylene diene monomer inner rubber layer is 2mm, the thickness of the polyester fiber woven fiber layer is 1mm, the thickness of the thermoplastic vulcanized rubber deformation-resistant layer is 5mm, and the thickness of the polyvinyl chloride outer rubber layer is 2 mm.
The utility model also provides a wind-powered electricity generation cooling tube has set gradually from inside to outside: the ethylene propylene diene monomer inner rubber layer is 1-5mm thick; the thickness of the polyester fiber woven fiber layer is 1-3 mm; a thermoplastic vulcanizate anti-deformation layer having a thickness of 2-6 mm; the thickness of the polyphenylene impermeable layer is 0.1-0.3 mm; the thickness of the polyvinyl chloride outer adhesive layer is 1-5 mm.
Preferably, the thickness of the ethylene propylene diene monomer inner rubber layer is 2mm, the thickness of the polyester fiber woven fiber layer is 3mm, the thickness of the thermoplastic vulcanized rubber deformation-resistant layer is 5mm, the thickness of the polyphenylene impermeable layer is 0.2mm, and the thickness of the polyvinyl chloride outer rubber layer is 2 mm.
The utility model also provides a wind-powered electricity generation cooling tube has set gradually from inside to outside: the thickness of the ethylene propylene diene monomer inner rubber layer is 1-5 mm; the thickness of the polyester fiber woven fiber layer is 1-3 mm; a thermoplastic vulcanizate deformation resistant layer having a thickness of 2-6 mm; the thickness of the polyphenylene impermeable layer is 0.1-0.3 mm; the thickness of the polyvinyl chloride outer adhesive layer is 1-5 mm; the polyphenylene sulfide high-temperature resistant layer is 3-8mm thick.
Preferably, the thickness of the ethylene propylene diene monomer inner rubber layer is 2mm, the thickness of the polyester fiber woven fiber layer is 3mm, the thickness of the thermoplastic vulcanized rubber deformation-resistant layer is 5mm, the thickness of the polyphenylene seepage-proof layer is 0.2mm, the thickness of the polyvinyl chloride outer rubber layer is 2mm, and the thickness of the polyphenylene sulfide high-temperature-resistant layer is 5 mm.
The utility model provides a pair of wind-powered electricity generation cooling tube's beneficial effect lies in: the wind power cooling pipe is simple in structure and reasonable in design, and has good low permeability, low extraction, high strength, flame retardance, static resistance, aging resistance and abrasion resistance through the cooperative matching of all layers. Wherein: the inner rubber layer of the ethylene propylene diene monomer rubber is directly contacted with the cooling liquid, and the ethylene propylene diene monomer rubber is used as a main body material and has the characteristics of low permeability and low extraction; the polyester fiber woven fiber layer adopts a polyester fiber woven structure, so that the stiffness and strength of the interior of the wind power cooling pipe can be enhanced, and the interior is prevented from cracking; the polyvinyl chloride outer adhesive layer adopts polyvinyl chloride as a main material and has the characteristics of flame retardance, static resistance, aging resistance and excellent wear resistance; the thermoplastic vulcanized rubber deformation-resistant layer adopts thermoplastic vulcanized rubber as a main material, and has excellent permanent deformation resistance, tensile strength, high toughness, high resilience and electrical insulation performance; the polyphenylene is adopted as a main material of the polyphenylene seepage-proof layer, so that the polyphenylene seepage-proof layer has good seepage-proof and shock-resistant properties; the polyphenylene sulfide high-temperature resistant layer adopts polyphenylene sulfide as a main material and has good high-temperature resistance and corrosion resistance.
Drawings
Fig. 1 is a schematic view of the layered structure of example 1 of the present invention.
Fig. 2 is a schematic view of the layered structure of example 2 of the present invention.
Fig. 3 is a schematic view of the layered structure of example 3 of the present invention.
Fig. 4 is a schematic view of the layered structure of example 4 of the present invention.
In the figure: 100. an ethylene propylene diene monomer inner rubber layer; 200. weaving a fiber layer by using polyester fibers; 300. a polyvinyl chloride outer glue layer; 400. a thermoplastic vulcanizate anti-deformation layer; 500. a polyphenylene barrier layer; 600. polyphenylene sulfide high temperature resistant layer.
Detailed Description
The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. All other embodiments obtained by a person skilled in the art without any inventive step are within the scope of the present invention.
Example 1: a wind power cooling pipe.
Referring to fig. 1, a wind power cooling pipe is provided with:
the ethylene propylene diene monomer inner rubber layer 100 is directly contacted with cooling liquid, the ethylene propylene diene monomer inner rubber layer 100 is used as a main body material, has the characteristics of low permeability and low extraction, the thickness of the ethylene propylene diene monomer inner rubber layer 100 is 2mm, the thickness of the ethylene propylene diene monomer inner rubber layer 100 cannot be too large, otherwise, not only the production cost is increased, but also can reduce the overall flexibility of the wind power cooling pipe, the thickness of the ethylene propylene diene monomer inner rubber layer 100 cannot be too small, otherwise the overall low permeability and low extraction characteristics of the wind power cooling pipe cannot be ensured, and experiments show that, when the thickness of the ethylene propylene diene monomer inner rubber layer 100 is 2mm, the wind power cooling pipe can be ensured to have the characteristics of low permeability and low extraction, and can also keep good flexibility, facilitate the wiring of pipelines and have good cost performance and cost performance;
the polyester fiber woven fiber layer 200 is of a polyester fiber woven structure, the stiffness and strength of the interior of the wind power cooling pipe can be enhanced, and internal cracking can be prevented, the thickness of the polyester fiber woven fiber layer 200 is 1mm, the thickness of the polyester fiber woven fiber layer 200 is not too high, otherwise, not only can the production cost be increased, but also the overall flexibility of the wind power cooling pipe can be reduced, the pipeline arrangement is inconvenient, the thickness of the polyester fiber woven fiber layer 200 is not too low, otherwise, the stiffness and strength of the interior of the wind power cooling pipe cannot be enhanced, and the requirement for internal cracking can be prevented, and experiments show that when the thickness of the polyester fiber woven fiber layer 200 is 1mm, the stiffness and strength of the interior of the wind power cooling pipe can be enhanced, the requirement for internal cracking can be reduced, the production cost can be reduced, and the cost performance is high;
the polyvinyl chloride outer adhesive layer 300 adopts polyvinyl chloride as a main material, has the characteristics of flame retardance, static resistance, aging resistance and excellent abrasion resistance, the thickness of the polyvinyl chloride outer adhesive layer 300 is 2mm, and likewise, the thickness of the polyvinyl chloride outer adhesive layer 300 cannot be too large, otherwise not only the production cost is increased, but also can reduce the overall flexibility of the wind power cooling pipe, the thickness of the polyvinyl chloride outer rubber layer 300 cannot be too small, otherwise the requirements of the wind power cooling pipe on flame retardance, antistatic property, aging resistance and wear resistance cannot be met, experiments show that, when the thickness of the polyvinyl chloride outer rubber layer 300 is 2mm, the requirements of the wind power cooling pipe on flame retardance, antistatic property, aging resistance and wear resistance can be met, the wind power cooling pipe can keep good flexibility, wiring of a pipeline is facilitated, and cost performance are good.
Example 2: a wind power cooling pipe.
Referring to fig. 2, the wind power cooling pipe is provided with:
the ethylene propylene diene monomer inner rubber layer 100 is directly contacted with cooling liquid, the ethylene propylene diene monomer inner rubber layer 100 is used as a main body material, has the characteristics of low permeability and low extraction, the thickness of the ethylene propylene diene monomer inner rubber layer 100 is 2mm, the thickness of the ethylene propylene diene monomer inner rubber layer 100 cannot be too large, otherwise, the production cost is increased, but also can reduce the overall flexibility of the wind power cooling pipe, the thickness of the ethylene propylene diene monomer inner rubber layer 100 cannot be too small, otherwise the overall low permeability and low extraction characteristics of the wind power cooling pipe cannot be ensured, and experiments show that, when the thickness of the ethylene propylene diene monomer inner rubber layer 100 is 2mm, the wind power cooling pipe can be ensured to have the characteristics of low permeability and low extraction, and can also keep good flexibility, facilitate the wiring of pipelines and have good cost performance and cost performance;
the polyester fiber woven fiber layer 200 is of a polyester fiber woven structure, so that the internal stiffness and strength of the wind power cooling pipe can be enhanced, internal cracking can be prevented, the thickness of the polyester fiber woven fiber layer 200 is 1mm, the thickness of the polyester fiber woven fiber layer 200 is not too high, otherwise, not only can the production cost be increased, but also the overall flexibility of the wind power cooling pipe can be reduced, the pipeline arrangement is inconvenient, the thickness of the polyester fiber woven fiber layer 200 is not too low, otherwise, the internal stiffness and strength of the wind power cooling pipe cannot be enhanced, and the requirement for internal cracking can be prevented, experiments show that when the thickness of the polyester fiber woven fiber layer 200 is 1mm, the internal stiffness and strength of the wind power cooling pipe can be enhanced, the requirement for internal cracking can be reduced, the production cost can be reduced, and the cost performance is high;
the thermoplastic vulcanized rubber deformation-resistant layer 400 is made of thermoplastic vulcanized rubber as a main body material, and has excellent permanent deformation resistance, tensile strength, high toughness, high resilience and electrical insulation performance; the thickness of the thermoplastic vulcanized rubber deformation-resistant layer 400 is 5mm, the thickness of the thermoplastic vulcanized rubber deformation-resistant layer 400 is not too high, otherwise, the production cost is increased, the overall flexibility of the wind power cooling pipe is reduced, the pipeline arrangement is inconvenient, the thickness of the thermoplastic vulcanized rubber deformation-resistant layer 400 is not too low, otherwise, the requirements of the wind power cooling pipe on the performances such as permanent deformation resistance, high toughness, high resilience, electric insulation performance and the like cannot be met, experiments show that when the thickness of the thermoplastic vulcanized rubber deformation-resistant layer 400 is 5mm, the requirements of the wind power cooling pipe on the performances such as permanent deformation resistance, high toughness, high resilience, electric insulation performance and the like can be met, the production cost can be reduced, and the cost performance is high;
the polyvinyl chloride outer adhesive layer 300 adopts polyvinyl chloride as a main material, has the characteristics of flame retardance, static resistance, aging resistance and excellent abrasion resistance, the thickness of the polyvinyl chloride outer adhesive layer 300 is 2mm, and likewise, the thickness of the polyvinyl chloride outer adhesive layer 300 cannot be too large, which not only increases the production cost, but also can reduce the overall flexibility of the wind power cooling pipe, the thickness of the polyvinyl chloride outer rubber layer 300 cannot be too small, otherwise the requirements of the wind power cooling pipe on flame retardance, antistatic property, aging resistance and wear resistance cannot be met, experiments show that, when the thickness of the polyvinyl chloride outer rubber layer 300 is 2mm, the requirements of the wind power cooling pipe on flame retardance, antistatic property, aging resistance and wear resistance can be met, the wind power cooling pipe can keep good flexibility, wiring of a pipeline is facilitated, and cost performance are good.
Example 3: a wind power cooling pipe.
Referring to fig. 3, the wind power cooling pipe is provided with:
the ethylene propylene diene monomer inner rubber layer 100 is directly contacted with the cooling liquid, the ethylene propylene diene monomer inner rubber layer 100 is used as a main body material, has the characteristics of low permeability and low extraction, the thickness of the ethylene propylene diene monomer inner rubber layer 100 is 2mm, the thickness of the ethylene propylene diene monomer inner rubber layer 100 cannot be too large, otherwise, not only the production cost is increased, but also can reduce the overall flexibility of the wind power cooling pipe, the thickness of the ethylene propylene diene monomer inner rubber layer 100 cannot be too small, otherwise the overall low permeability and low extraction characteristics of the wind power cooling pipe cannot be ensured, and experiments show that, when the thickness of the ethylene propylene diene monomer inner rubber layer 100 is 2mm, the wind power cooling pipe can be ensured to have the characteristics of low permeability and low extraction, and can also keep good flexibility, facilitate the wiring of pipelines and have good cost performance and cost performance;
the polyester fiber woven fiber layer 200 is of a polyester fiber woven structure, so that the internal stiffness and strength of the wind power cooling pipe can be enhanced, internal cracking can be prevented, the thickness of the polyester fiber woven fiber layer 200 is 1mm, the thickness of the polyester fiber woven fiber layer 200 is not too high, otherwise, not only can the production cost be increased, but also the overall flexibility of the wind power cooling pipe can be reduced, the pipeline arrangement is inconvenient, the thickness of the polyester fiber woven fiber layer 200 is not too low, otherwise, the internal stiffness and strength of the wind power cooling pipe cannot be enhanced, and the requirement for internal cracking can be prevented, experiments show that when the thickness of the polyester fiber woven fiber layer 200 is 1mm, the internal stiffness and strength of the wind power cooling pipe can be enhanced, the requirement for internal cracking can be reduced, the production cost can be reduced, and the cost performance is high;
the thermoplastic vulcanized rubber deformation-resistant layer 400 is made of thermoplastic vulcanized rubber as a main material, and has excellent permanent deformation resistance, tensile strength, high toughness, high resilience and electrical insulation performance; the thickness of the thermoplastic vulcanized rubber deformation-resistant layer 400 is 5mm, the thickness of the thermoplastic vulcanized rubber deformation-resistant layer 400 is not too high, otherwise, the production cost is increased, the overall flexibility of the wind power cooling pipe is reduced, the pipeline arrangement is inconvenient, the thickness of the thermoplastic vulcanized rubber deformation-resistant layer 400 is not too low, otherwise, the requirements of the wind power cooling pipe on the performances such as permanent deformation resistance, high toughness, high resilience, electric insulation performance and the like cannot be met, experiments show that when the thickness of the thermoplastic vulcanized rubber deformation-resistant layer 400 is 5mm, the requirements of the wind power cooling pipe on the performances such as permanent deformation resistance, high toughness, high resilience, electric insulation performance and the like can be met, the production cost can be reduced, and the cost performance is high;
the polyphenyl alkene impermeable layer 500 is made of polyphenyl alkene, the polyphenyl alkene impermeable layer 500 has good impermeable performance and impact resistance, the thickness of the polyphenyl alkene impermeable layer is 0.2mm, the thickness of the polyphenyl alkene impermeable layer 500 is not too high, otherwise, the production cost is increased, the overall flexibility of the wind power cooling pipe is reduced, the pipeline arrangement is inconvenient, the thickness of the polyphenyl alkene impermeable layer 500 is not too low, the increase of the impermeable performance and the impact resistance is not obvious, experiments show that when the thickness of the polyphenyl alkene impermeable layer 500 is 0.2mm, the impermeable performance and the impact resistance of the wind power cooling pipe can be obviously improved, the production cost is not greatly improved, and the cost performance is high;
the polyvinyl chloride outer adhesive layer 300 adopts polyvinyl chloride as a main material, has the characteristics of flame retardance, static resistance, aging resistance and excellent abrasion resistance, the thickness of the polyvinyl chloride outer adhesive layer 300 is 2mm, and likewise, the thickness of the polyvinyl chloride outer adhesive layer 300 cannot be too large, otherwise not only the production cost is increased, but also can reduce the overall flexibility of the wind power cooling pipe, the thickness of the polyvinyl chloride outer rubber layer 300 cannot be too small, otherwise the requirements of the wind power cooling pipe on flame retardance, antistatic property, aging resistance and wear resistance cannot be met, experiments show that, when the thickness of the polyvinyl chloride outer rubber layer 300 is 2mm, the requirements of the wind power cooling pipe on flame retardance, antistatic property, aging resistance and wear resistance can be met, the wind power cooling pipe can keep good flexibility, wiring of a pipeline is facilitated, and cost performance are good.
Example 4: a wind power cooling pipe.
Referring to fig. 4, the wind power cooling pipe is provided with:
the ethylene propylene diene monomer inner rubber layer 100 is directly contacted with cooling liquid, the ethylene propylene diene monomer inner rubber layer 100 is used as a main body material, has the characteristics of low permeability and low extraction, the thickness of the ethylene propylene diene monomer inner rubber layer 100 is 2mm, the thickness of the ethylene propylene diene monomer inner rubber layer 100 cannot be too large, otherwise, not only the production cost is increased, but also can reduce the overall flexibility of the wind power cooling pipe, the thickness of the ethylene propylene diene monomer inner rubber layer 100 cannot be too small, otherwise the overall low permeability and low extraction characteristics of the wind power cooling pipe cannot be ensured, and experiments show that, when the thickness of the ethylene propylene diene monomer inner rubber layer 100 is 2mm, the wind power cooling pipe can be ensured to have the characteristics of low permeability and low extraction, and can also keep good flexibility, facilitate the wiring of pipelines and have good cost performance and cost performance;
the polyester fiber woven fiber layer 200 is of a polyester fiber woven structure, so that the internal stiffness and strength of the wind power cooling pipe can be enhanced, internal cracking can be prevented, the thickness of the polyester fiber woven fiber layer 200 is 1mm, the thickness of the polyester fiber woven fiber layer 200 is not too high, otherwise, not only can the production cost be increased, but also the overall flexibility of the wind power cooling pipe can be reduced, the pipeline arrangement is inconvenient, the thickness of the polyester fiber woven fiber layer 200 is not too low, otherwise, the internal stiffness and strength of the wind power cooling pipe cannot be enhanced, and the requirement for internal cracking can be prevented, experiments show that when the thickness of the polyester fiber woven fiber layer 200 is 1mm, the internal stiffness and strength of the wind power cooling pipe can be enhanced, the requirement for internal cracking can be reduced, the production cost can be reduced, and the cost performance is high;
the thermoplastic vulcanized rubber deformation-resistant layer 400 is made of thermoplastic vulcanized rubber as a main body material, and has excellent permanent deformation resistance, tensile strength, high toughness, high resilience and electrical insulation performance; the thickness of the thermoplastic vulcanized rubber deformation-resistant layer 400 is 5mm, the thickness of the thermoplastic vulcanized rubber deformation-resistant layer 400 is not too high, otherwise, the production cost is increased, the overall flexibility of the wind power cooling pipe is reduced, the pipeline arrangement is inconvenient, the thickness of the thermoplastic vulcanized rubber deformation-resistant layer 400 is not too low, otherwise, the requirements of the wind power cooling pipe on the performances such as permanent deformation resistance, high toughness, high resilience, electric insulation performance and the like cannot be met, experiments show that when the thickness of the thermoplastic vulcanized rubber deformation-resistant layer 400 is 5mm, the requirements of the wind power cooling pipe on the performances such as permanent deformation resistance, high toughness, high resilience, electric insulation performance and the like can be met, the production cost can be reduced, and the cost performance is high;
the polyphenyl alkene impermeable layer 500 is made of polyphenyl alkene, the polyphenyl alkene impermeable layer 500 has good impermeable performance and impact resistance, the thickness of the polyphenyl alkene impermeable layer is 0.2mm, the thickness of the polyphenyl alkene impermeable layer 500 is not too high, otherwise, the production cost is increased, the overall flexibility of the wind power cooling pipe is reduced, the pipeline arrangement is inconvenient, the thickness of the polyphenyl alkene impermeable layer 500 is not too low, the increase of the impermeable performance and the impact resistance is not obvious, experiments show that when the thickness of the polyphenyl alkene impermeable layer 500 is 0.2mm, the impermeable performance and the impact resistance of the wind power cooling pipe can be obviously improved, the production cost is not greatly improved, and the cost performance is high;
the polyvinyl chloride outer adhesive layer 300 adopts polyvinyl chloride as a main material, has the characteristics of flame retardance, static resistance, aging resistance and excellent abrasion resistance, the thickness of the polyvinyl chloride outer adhesive layer 300 is 2mm, and likewise, the thickness of the polyvinyl chloride outer adhesive layer 300 cannot be too large, otherwise not only the production cost is increased, but also can reduce the overall flexibility of the wind power cooling pipe, the thickness of the polyvinyl chloride outer rubber layer 300 cannot be too small, otherwise the requirements of the wind power cooling pipe on flame retardance, antistatic property, aging resistance and wear resistance cannot be met, experiments show that, when the thickness of the polyvinyl chloride outer adhesive layer 300 is 2mm, the requirements of the wind power cooling pipe on flame retardance, antistatic property, aging resistance and wear resistance can be met, the wind power cooling pipe can keep good flexibility, the wiring of a pipeline is facilitated, and the cost performance are good;
the polyphenylene sulfide high-temperature resistant layer 600 is made of polyphenylene sulfide as a main material, and has good high-temperature resistance and corrosion resistance, the thickness of the polyphenylene sulfide high-temperature resistant layer 600 is 5mm, the thickness of the polyphenylene sulfide high-temperature resistant layer 600 cannot be too large, otherwise, not only can the production cost be increased, but also the overall flexibility of the wind power cooling pipe can be reduced, the thickness of the polyphenylene sulfide high-temperature resistant layer 600 cannot be too small, otherwise, the requirements of the wind power cooling pipe on high-temperature resistance and corrosion resistance cannot be met, experiments show that when the thickness of the polyphenylene sulfide high-temperature resistant layer 600 is 5mm, the requirements of the wind power cooling pipe on high-temperature resistance and corrosion resistance can be met, the wind power cooling pipe can maintain good flexibility, the wiring of pipelines is facilitated, and the cost ratio is good.
The above description is a preferred embodiment of the present invention, but the present invention should not be limited to the disclosure of the embodiment and the accompanying drawings, and therefore, all equivalents and modifications that can be accomplished without departing from the spirit of the present invention are within the protection scope of the present invention.
Claims (9)
1. The utility model provides a wind-powered electricity generation cooling tube which characterized in that has set gradually from inside to outside:
the thickness of the ethylene propylene diene monomer inner rubber layer is 1-5 mm;
the thickness of the polyester fiber woven fiber layer is 1-3 mm;
the thickness of the polyvinyl chloride outer adhesive layer is 1-5 mm.
2. The wind power cooling tube of claim 1, wherein: the thickness of the ethylene propylene diene monomer inner rubber layer is 1-3mm, the thickness of the polyester fiber woven fiber layer is 1-2mm, and the thickness of the polyvinyl chloride outer rubber layer is 1-3 mm.
3. The wind power cooling tube of claim 2, wherein: the thickness of the ethylene propylene diene monomer inner rubber layer is 2mm, the thickness of the polyester fiber woven fiber layer is 1mm, and the thickness of the polyvinyl chloride outer rubber layer is 2 mm.
4. The utility model provides a wind-powered electricity generation cooling tube which characterized in that has set gradually from inside to outside:
the ethylene propylene diene monomer inner rubber layer is 1-5mm thick;
the thickness of the polyester fiber woven fiber layer is 1-3 mm;
a thermoplastic vulcanizate deformation resistant layer having a thickness of 2-6 mm;
the thickness of the polyvinyl chloride outer adhesive layer is 1-5 mm.
5. The wind power cooling tube of claim 4, wherein: the thickness of ethylene propylene diene monomer inner rubber layer is 2mm, the thickness of polyester fiber woven fiber layer is 1mm, the thickness of thermoplastic vulcanized rubber anti-deformation layer is 5mm, and the thickness of polyvinyl chloride outer rubber layer is 2 mm.
6. The utility model provides a wind-powered electricity generation cooling tube which characterized in that has set gradually from inside to outside:
the ethylene propylene diene monomer inner rubber layer is 1-5mm thick;
the thickness of the polyester fiber woven fiber layer is 1-3 mm;
a thermoplastic vulcanizate anti-deformation layer having a thickness of 2-6 mm;
the thickness of the polyphenylene impermeable layer is 0.1-0.3 mm;
the thickness of the polyvinyl chloride outer adhesive layer is 1-5 mm.
7. The wind power cooling tube of claim 6, wherein: the thickness of the ethylene propylene diene monomer inner rubber layer is 2mm, the thickness of the polyester fiber woven fiber layer is 3mm, the thickness of the thermoplastic vulcanized rubber anti-deformation layer is 5mm, the thickness of the polyphenylene seepage-proof layer is 0.2mm, and the thickness of the polyvinyl chloride outer rubber layer is 2 mm.
8. The utility model provides a wind-powered electricity generation cooling tube which characterized in that has set gradually from inside to outside:
the ethylene propylene diene monomer inner rubber layer is 1-5mm thick;
the thickness of the polyester fiber woven fiber layer is 1-3 mm;
a thermoplastic vulcanizate anti-deformation layer having a thickness of 2-6 mm;
the thickness of the polyphenylene impermeable layer is 0.1-0.3 mm;
the thickness of the polyvinyl chloride outer adhesive layer is 1-5 mm;
the polyphenylene sulfide high-temperature resistant layer is 3-8mm thick.
9. The wind power cooling tube of claim 8, wherein: the thickness of the ethylene propylene diene monomer inner rubber layer is 2mm, the thickness of the polyester fiber woven fiber layer is 3mm, the thickness of the thermoplastic vulcanized rubber deformation-resistant layer is 5mm, the thickness of the polyphenylene seepage-proof layer is 0.2mm, the thickness of the polyvinyl chloride outer rubber layer is 2mm, and the thickness of the polyphenylene sulfide high-temperature-resistant layer is 5 mm.
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CN202220152246.0U CN217272481U (en) | 2022-01-18 | 2022-01-18 | Wind power cooling pipe |
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