Oil Resistance NBR Plastic Rubber Foam Tubes Insulation
benefits of Using oil-Resistant NBR plastic Rubber Foam tubes Insulation Oil resistance NBR plastic rubber foam tubes insulation is a…
benefits of Using oil-Resistant NBR plastic Rubber Foam tubes Insulation
Oil resistance NBR plastic rubber foam tubes insulation is a versatile and durable material that offers a wide range of benefits for various applications. From industrial settings to residential construction, this type of insulation provides excellent protection against oil, water, and other liquids, making it an ideal choice for environments where exposure to these substances is common. One of the key benefits of using oil-resistant NBR plastic rubber foam tubes insulation is its ability to withstand harsh conditions. Whether it’s extreme temperatures, high levels of moisture, or exposure to chemicals, this type of insulation is designed to hold up under tough circumstances. This makes it a reliable option for industries such as Oil and gas, automotive, and manufacturing, where equipment and machinery are often subjected to challenging environments. In addition to its durability, oil-resistant NBR plastic rubber foam tubes insulation also offers excellent thermal insulation properties. By effectively trapping heat and preventing energy loss, this material helps to maintain a consistent temperature in buildings and equipment, reducing energy costs and improving overall efficiency. This makes it a cost-effective solution for both residential and commercial applications, where energy savings are a top priority. Furthermore, oil-resistant NBR plastic rubber foam tubes insulation is easy to install and maintain, making it a convenient choice for a wide range of projects. With its flexible and lightweight design, this material can be easily cut and shaped to fit any space, allowing for quick and efficient installation. Additionally, its resistance to mold and mildew makes it a low-Maintenance option that requires minimal upkeep over timehow to properly Install and Maintain Oil-Resistant NBR Plastic Rubber Foam Tubes Insulation
Oil resistance NBR plastic rubber foam tubes insulation is a popular choice for many industries due to its ability to withstand exposure to oils and other petroleum–based substances. Proper installation and maintenance of this type of insulation are crucial to ensure its effectiveness and longevity. In this article, we will discuss the steps involved in installing and maintaining oil-resistant NBR plastic rubber foam tubes insulation. When installing oil-resistant NBR plastic rubber foam tubes insulation, it is important to first prepare the surface that the insulation will be applied to. The surface should be clean, dry, and free of any debris or contaminants that could affect the adhesion of the insulation. Any existing insulation should be removed, and the surface should be inspected for any damage that may need to be Repaired before installing the new insulation. china wholesale a53 Grb Sch40 Sch80 carbon steel Tube for Oil and Gas drilling with High quality Once the surface is prepared, the next step is to measure and cut the insulation to the appropriate size. It is important to ensure that the insulation fits snugly around the Pipe or duct that it is being applied to, with no gaps or overlaps. The insulation should be secured in place using adhesive or tape, making sure to Seal any seams or joints to prevent air Leakage.Labels a | Calculated Mass c | ||||||||||
Nominal linear Mass T& C b,c | wall Thick- ness | em, Mass Gain or Loss Due to End finishing d | |||||||||
Outside diameter | Inside Diameter | Drift Diameter | Plain- end | kg | |||||||
Round Thread | Buttress Thread | ||||||||||
wpe | |||||||||||
D | kg/m | t | D | mm | kg/m | Short | Long | RC | SCC | ||
mm | mm | mm | |||||||||
1 | 2 | 3 | 4 | 5 | 6 | 7 | 8 | 9 | 10 | 11 | 12 |
13 3/8 | 48 | 339.72 | 71.43 | 8.38 | 322.96 | 318.99 | 68.48 | 15.04 | — | — 17.91 | — |
13 3/8 | 54.5 | 339.72 | 81.1 | 9.65 | 320.42 | 316.45 | 78.55 | 13.88 | — | 16.44 | — |
13 3/8 | 61 | 339.72 | 90.78 | 10.92 | 317.88 | 313.91 | 88.55 | 12.74 | — | 14.97 | — |
13 3/8 | 68 | 339.72 | 101.19 | 12.19 | 315.34 | 311.37 | 98.46 | 11.61 | — | 14.97 | — |
13 3/8 | 68 | 339.72 | 101.19 | 12.19 | 315.34 | 311.37 | 98.46 | 11.67 f | — | 14.33 | — |
13 3/8 | 72 | 339.72 | 107.15 | 13.06 | 313.6 | 311.15 e | 105.21 | 10.98 | — | 13.98 | — |
13 3/8 | 72 | 339.72 | 107.15 | 13.06 | 313.6 | 311.15 e 309.63 309.63 | 105.21 | 10.91 f | — | 14.33 | — |
13 3/8 | 72 | 339.72 | 107.15 | 13.06 | 313.6 | 105.21 | 10.98 | — | 13.98 | — | |
13 3/8 | 72 | 339.72 | 107.15 | 13.06 | 313.6 | 105.21 | 10.91 e | — | — | ||
16 | 65 | 406.4 | 96.73 | 9.53 | 387.4 | 382.57 | 96.73 | 18.59 | — | — 20.13 | — |
16 | 75 | 406.4 | 111.61 | 11.13 | 384.1 | 379.37 | 108.49 | 16.66 | — | 18.11 | — |
16 | 84 | 406.4 | 125.01 | 12.57 | 381.3 | 376.48 | 122.09 | 14.92 | — | — | — |
16 | 109 | 406.4 | 162.21 | 16.66 | 373.1 | 368.3 | 160.13 | — | — | — | |
18 5/8 | 87.5 | 473.08 | 130.21 | 11.05 | 450.98 | 446.22 | 125.91 | 33.6 | — | 39.25 | — |
20 | 94 | 508 | 139.89 | 11.13 | 485.7 | 480.97 | 136.38 | 20.5 | 27.11 | 24.78 | — |
20 | 94 | 508 | 139.89 | 11.13 | 485.7 | 480.97 | 136.38 | 20.61 | 27.26 g 24.27 17.84 | 24.78 | — |
20 | 106.5 | 508 | 158.49 | 12.7 | 482.6 | 477.82 | 155.13 | 18.22 | 22 | — | |
20 | 133 | 508 | 197.93 | 16.13 | 475.7 | 470.97 | 195.66 | 13.03 | 16.02 | — | |
NOTE See also Figures D.1, D.2, and D.3. | |||||||||||
a Labels are for information and assistance in ordering. | |||||||||||
b Nominal linear masses, threaded and coupled (Column 4) are shown for information only. | |||||||||||
c The densities of martensitic chromium steels ( L80 types 9Cr and 13Cr) are less than those of carbon steels; The masses shown are therefore not accurate for martensitic chromium steels; A mass correction factor of 0.989 shall be used. | |||||||||||
d Mass gain or loss due to end finishing; See 8.5. | |||||||||||
e Drift diameter for most common bit size; This drift diameter shall be specified in the purchase agreement and marked on the pipe; See 8.10 for drift requirements. | |||||||||||
f Based on 758 mPa minimum yield strength or greater. | |||||||||||
g Based on 379 mPa minimum yield strength. |