API Manufacturer Oil Sidetracking Tools Deviator/Casing Whipstock /Window Deflector
Introduction to API manufacturer Oil Sidetracking tools API Manufacturer Oil Sidetracking Tools Deviator/Casing Whipstock /Window Deflector Pencil case the Oil and gas industry is a complex and ever-evolving sector that requires innovative solutions to maximize production and efficiency. One crucial aspect of this industry is the ability to sidetrack wells, which involves drilling a new…
Introduction to API manufacturer Oil Sidetracking tools
API Manufacturer Oil Sidetracking Tools Deviator/Casing Whipstock /Window Deflector Pencil case the Oil and gas industry is a complex and ever-evolving sector that requires innovative solutions to maximize production and efficiency. One crucial aspect of this industry is the ability to sidetrack wells, which involves drilling a new hole from an existing wellbore. To achieve this, API Manufacturers have developed a range of oil sidetracking tools, including deviators, casing whipstocks, and window deflectors. these tools play a vital role in the sidetracking process by providing the necessary support and guidance to redirect the drilling path. they are designed to withstand the harsh conditions of oil and gas wells, ensuring reliable performance and longevity. API manufacturers adhere to strict industry standards to guarantee the quality and safety of these tools. The deviator is a key component in the sidetracking process. It is a tool that is inserted into the wellbore to guide the drill bit in a new direction. The deviator is typically made of high–strength materials, such as alloy steel, to withstand the forces exerted during drilling. It is designed with precision to ensure accurate steering of the drill bit, allowing for precise control over the drilling path. Another essential tool in the sidetracking process is the casing whipstock. This tool is used to create a window in the casing, allowing for the drilling of a new hole. The casing whipstock is typically made of high-strength steel and is designed to withstand the forces exerted during drilling. It is inserted into the wellbore and anchored securely in place to provide a stable platform for the drill bit. The casing whipstock is designed with a ramp that guides the drill bit in the desired direction, ensuring accurate and controlled drilling.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. |